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ATSB TRANSPORT SAFETY REPORT
Aviation Occurrence Investigation – AO-2007-017
Final
Fuel starvation
Jundee Airstrip, WA – 26 June 2007
VH-XUE
Empresa Brasileira de Aeronáutica S.A., EMB-120ER
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ATSB TRANSPORT SAFETY REPORT
Aviation Occurrence Investigation
AO-2007-017
Final
Fuel starvation
Jundee Airstrip, WA – 26 June 2007
VH-XUE
Empresa Brasileira de Aeronáutica S.A.,
EMB-120ER
Released in accordance with section 25 of the Transport Safety Investigation Act 2003
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Published by: Australian Transport Safety Bureau
Postal address: PO Box 967 020 616; from overseas + 61 2 6257 4150
Office location: 62 Northbourne Ave, Canberra City, Australian Capital Territory
Telephone: 1800 020 616; from overseas + 61 2 6257 4150
Accident and incident notification: 1800 011 034 (24 hours)
Facsimile: 02 6247 3117; from overseas + 61 2 6247 3117
E-mail: [email protected]
Internet: www.atsb.gov.au
© Commonwealth of Australia 2009.
This work is copyright. In the interests of enhancing the value of the information contained in this
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organisations. Where you want to use their material you will need to contact them directly.
Subject to the provisions of the Copyright Act 1968, you must not make any other use of the
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Please direct requests for further information or authorisation to:
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www.ag.gov.au/cca
ISBN and formal report title: see ‘Document retrieval information’ on page vii.
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CONTENTS
EXECUTIVE SUMMARY ................................................................................... ix
THE AUSTRALIAN TRANSPORT SAFETY BUREAU ............................... xiv
1 FACTUAL INFORMATION ........................................................................ 1
1.1 History of the flight .............................................................................. 1
1.2 Injuries to persons ................................................................................. 7
1.3 Damage to aircraft ................................................................................ 7
1.4 Personnel information ........................................................................... 7
1.4.1 Pilot in command ................................................................ 7
1.4.2 Copilot ................................................................................ 8
1.5 Aircraft information .............................................................................. 8
1.5.1 Instrument panel layout ...................................................... 8
1.5.2 Cockpit alarm and indications ............................................ 9
1.5.3 Engine instruments ........................................................... 10
1.5.4 Indications in the event of fuel starvation ......................... 11
1.5.5 Fuel quantity indicating system ........................................ 12
1.5.6 Fuel totaliser ..................................................................... 13
1.5.7 Dripless measuring sticks ................................................. 14
1.5.8 Fuel low-level warning system ......................................... 15
1.5.9 Fuel system maintenance history ...................................... 15
1.5.10 Examination of the fuel quantity indicating system.......... 16
1.6 Meteorological information ................................................................ 17
1.6.1 Local weather conditions .................................................. 17
1.6.2 Sun position information .................................................. 17
1.7 Aids to navigation ............................................................................... 17
1.8 Communications ................................................................................. 17
1.9 Aerodrome information ...................................................................... 18
1.10 Flight recorders ................................................................................... 18
1.11 Tests and research ............................................................................... 20
1.11.1 Flight simulator replication of the occurrence by other
pilots ................................................................................. 20
1.12 Fuel quantity measurement processes................................................. 20
1.12.1 Regulatory requirements and guidance ............................. 20
1.12.2 Operator’s fuel quantity measurement procedures ........... 22
1.12.3 Use of flight logs............................................................... 23
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1.12.4 Refuelling to a known quantity ......................................... 24
1.12.5 Discrepancies between recorded and actual fuel
quantities ........................................................................... 24
1.12.6 Cross-checks of total fuel quantity at departure ............... 25
1.12.7 Residual fuel quantity variations between days ................ 25
1.12.8 Use of dripless measuring sticks ....................................... 26
1.12.9 Recording of fuel used by maintenance personnel ........... 26
1.12.10 Auditing of fuel use and recording practices .................... 26
1.13 Related fuel quantity occurrences ....................................................... 27
1.13.1 Previous EMB-120 occurrence in Australia (14
January 2005) .................................................................... 27
1.13.2 Other EMB-120 fuel-related occurrences ......................... 27
1.13.3 Other fuel-related occurrences .......................................... 28
1.14 Communication of important safety information to the industry ....... 28
1.15 Operational procedures ....................................................................... 29
1.15.1 Crew resource management .............................................. 29
1.15.2 Procedures for go-around .................................................. 30
1.15.3 Procedures for operations on unpaved surfaces ................ 31
1.16 Flight crew endorsement and line training requirements .................... 32
1.16.1 Regulatory requirements ................................................... 32
1.16.2 Operator’s requirements ................................................... 32
1.16.3 Other EMB-120 operators training requirements ............. 33
1.17 Flight simulators ................................................................................. 34
1.17.1 Background ....................................................................... 34
1.17.2 Australian regulatory requirements................................... 34
1.17.3 Overseas regulatory requirements..................................... 35
1.17.4 Use of simulators by Australian regional operators of
turboprop aircraft with 19 seat or greater capacity ........... 36
1.17.5 Transport category turboprop aircraft simulators in
Australia ............................................................................ 37
1.18 Recent serious occurrences involving transport category
turboprop aircraft in Australia where aircraft handling was a
factor ................................................................................................... 38
2 Analysis .......................................................................................................... 39
2.1 Overview ............................................................................................ 39
2.2 Fuel quantity indicating system faults ................................................ 39
2.3 Fuel quantity measurement ................................................................. 40
2.3.1 Regulatory guidance ......................................................... 40
2.3.2 Operators procedures and practices for fuel quantity
check ................................................................................. 41
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2.3.3 Auditing of flight log fuel records .................................... 41
2.3.4 Fuel low level warning system ......................................... 42
2.4 Flight crew performance ..................................................................... 42
2.5 System for communicating important occurrence information to
operators ............................................................................................. 43
3 FINDINGS ..................................................................................................... 45
3.1 Contributing safety factors ................................................................. 45
3.2 Other safety factors ............................................................................. 45
4 SAFETY ACTIONS...................................................................................... 47
4.1 Aircraft operator ................................................................................. 47
4.1.1 Fuel measuring procedures ............................................... 47
4.1.2 Pilots inadequately prepared for event .............................. 47
4.2 Civil Aviation Safety Authority .......................................................... 48
4.2.1 Fuel measuring procedures ............................................... 48
4.2.2 Regulatory guidance for fuel quantity measurement ........ 50
4.2.3 No regulation for simulator training ................................. 51
4.2.4 Requirements for endorsement training ............................ 53
4.2.5 Dissemination of safety information ................................. 53
4.2.6 Other safety action taken by the Civil Aviation Safety
Authority ........................................................................... 54
4.3 Aircraft certification authorities ......................................................... 54
4.3.1 Fuel low level warning ..................................................... 54
4.4 Aircraft manufacturer ......................................................................... 55
4.4.1 Dissemination of safety information ................................. 55
4.4.2 Other safety action taken by the aircraft manufacturer ..... 55
4.5 Ansett Aviation Training .................................................................... 57
4.5.1 No EMB-120 flight simulator training facility in
Australia ............................................................................ 57
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APPENDIX A: FUEL LOW LEVEL WARNING SYSTEMS:
PREVIOUS OCCURRENCES AND RECOMMENDATIONS ............... 59
APPENDIX B: FUEL STARVATION-RELATED
OCCURRENCES INVOLVING AUSTRALIAN REGISTERED
AIRCRAFT OTHER THAN EMB-120 AIRCRAFT SINCE
JANUARY 2005 63
APPENDIX C: RECENT SERIOUS OCCURRENCES
INVOLVING TRANSPORT CATEGORY TURBOPROP
AIRCRAFT IN AUSTRALIA WHERE AIRCRAFT HANDLING
WAS A FACTOR .......................................................................................... 67
APPENDIX D: EMBRAER SERVICE NEWSLETTER ...................... 73
APPENDIX E: SOURCES AND SUBMISSIONS .................................. 75
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DOCUMENT RETRIEVAL INFORMATION
Report No.
AO-2007-017
Publication date
8 July 2009
No. of pages
89
ISBN
978-1-921602-83-2
Publication title
Fuel starvation - Jundee Airstrip, WA - 26 June 2007 - VH-XUE, Empresa Brasileira de
Aeronáutica S.A., EMB-120ER
Prepared by
Australian Transport Safety Bureau
PO Box 967, Civic Square ACT 2608 Australia
www.atsb.gov.au
Reference No.
INFRA-08563
Abstract
On 26 June 2007 at 0639 Western Standard Time, an Empresa Brasileira de Aeronáutica S.A.
EMB-120ER aircraft, registered VH-XUE, departed Perth, WA on a contracted passenger
charter flight to Jundee Airstrip. There were two pilots, one flight attendant, and 28 passengers
on the aircraft.
While passing through 400 ft above ground level on final approach to Jundee Airstrip, with
flaps 45 set, the aircraft drifted left of the runway centreline. When a go-around was initiated,
the aircraft aggressively rolled and yawed left, causing the crew control difficulties. The crew
did not immediately complete the go-around procedures. Normal aircraft control was regained
when the landing gear was retracted about 3 minutes later.
The left engine had sustained a total power loss following fuel starvation, because the left fuel
tank was empty. The investigation identified safety factors associated with the fuel quantity
indicating system, the ability of the crew to recognise the left engine power loss, and their
performance during the go-around. There were clear indications that the operator’s fuel
quantity measurement procedures and practices were not sufficiently robust to ensure that a
quantity indication error was detected. The failure of that risk control provided the opportunity
for other safety barriers involving both the recognition of, and the crew’s response to, the
power loss, to be tested. Organisational safety factors involving regulatory guidance, the
operator’s procedures, and flight crew practices were identified in those two areas. The
operator introduced revised procedures for measuring fuel quantity and the Civil Aviation
Safety Authority (CASA) initiated a project to amend the guidance to provide better clarity and
emphasis.
The crew’s endorsement and other training did not include simulator training and did not
adequately prepare them for the event. There was no EMB-120 flight simulator facility in
Australia and no Australian regulatory requirement for simulator training. In March 2009, an
EMB-120 flight simulator came into operation in Melbourne, Vic. A workshop and discussion
forum was conducted on 27 to 28 April 2009 for Australian Embraer 120 aircraft operators. All
those operators were expected to commence utilising the simulator for flight crew endorsement
training following that workshop.
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EXECUTIVE SUMMARY
On 26 June 2007 at about 0806 Western Standard Time, an Empresa Brasileira de
Aeronáutica S.A. EMB-120ER (EMB-120ER) aircraft, registered VH-XUE, on a
contracted passenger charter flight to Jundee Airstrip, WA almost impacted terrain
after the crew lost normal control of the aircraft when they initiated a go-around at
about 300 ft above ground level (AGL) on final approach at Jundee Airstrip. On
board the aircraft were two pilots, one flight attendant, and 28 passengers.
The aircraft was in the landing configuration at the time, and the decision to go
around was taken because the aircraft had become misaligned with the runway on
late final approach. Unknown to the crew was the fact that the left engine had
ceased operating a short time earlier. When the crew advanced the engine power
levers to commence the go-around, they were startled when the aircraft yawed and
rolled left aggressively in response to the engine power asymmetry. The copilot,
who was the handling pilot, felt that he could not control the aircraft and asked the
pilot in command to assist him on the controls. That situation, along with the
aircraft’s proximity to the ground, appeared to have distracted the crew to the extent
that they did not complete all of the essential go-around procedures. As a result, the
landing gear and flaps were not configured correctly until much later in the go-
around sequence. The recorded performance of the aircraft during the go-around
indicated that the avoidance of a collision with terrain was fortuitous with the
altitude of the aircraft decreasing to 50 ft AGL at its lowest point.
The crew recalled that they had noticed during the go-around, the red master
warning captions for oil pressure for the left engine, and a fuel master caution. After
the landing gear had retracted, they turned their attention to those captions and saw
that other captions, concerning the left engine, were also illuminated. They
observed that the fuel quantity gauges were indicating just over 200 kg per side.
The crew then completed the ‘engine failure in-flight’ actions. They reported that
there was an immediate and significant improvement in aircraft performance when
the left engine condition lever was placed in the feather position.
At that stage, the aircraft was heading in the approximate direction of Wiluna, about
30 km south-west of Jundee. The crew elected to continue in that direction and
conducted a single-engine landing at Wiluna.
When the aircraft was examined at Wiluna, the right fuel gauge was indicating 150
kg and the left gauge 300 kg. A physical check revealed that the right tank
contained 150 kg of fuel and that the left tank was empty. The aircraft’s flight log
indicated that there was 1,190 kg of fuel on board prior to the departure from Perth.
Normal fuel consumption for the flight Perth to Jundee was in the range 750 - 900
kg, depending on atmospheric conditions.
The investigation focused on two main aspects – fuel quantity management and
aircraft handling.
Fuel quantity management
Examination of the aircraft revealed that the outboard capacitance probe in the left
tank quantity indicating system had failed. Abrasive damage found on the probe
wiring loom, where it had rubbed against the airframe, had allowed electrical short
circuiting, resulting in the failure of the probe.
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The aircraft was not equipped with a fuel low-level warning system. However, it
was fitted with dripless measuring sticks that provided a totally reliable means of
validating the fuel quantity on board the aircraft before flight.
From the examination of the operator’s flight logs, there were instances where
significant discrepancies between the recorded fuel at shutdown from the previous
day and the indicated fuel quantity before refuelling the following day, were
apparently ignored by flight crew. Use of the dripless measuring sticks by flight
crew to validate fuel quantity had been recorded in flight logs on only two
occasions between 1 April and 25 June 2007.
There was evidence that flight crews did not have a proper understanding of the
reasoning behind the fuel quantity check procedures, and the necessity for an
independent validation of the fuel quantity by a totally reliable method. That
situation resulted in a culture existing amongst crews of undue reliance being
placed on the accuracy and reliability of the EMB-120 fuel quantity indicating
system.
The Civil Aviation Safety Authority (CASA) published Civil Aviation Advisory
Publication (CAAP) 234-1(1), which contained guidance regarding the
establishment of fuel quantity before flight. In broad terms, the CAAP allowed two
options for establishing fuel on board:
• full tanks, or ‘a totally reliable and accurately graduated dipstick, sight gauge,
drip gauge or tank tab reading’; or
• a cross-check by at least two different methods.
The CAAP did not clearly indicate whether, or why, one option had advantages, or
was preferred, over the other. The CAAP, in effect, allowed operators to choose the
method that suited, or perhaps was most convenient, to them. Because of
operational considerations, many aircraft, including the EMB-120, were rarely
operated with full tanks. The use of one of the ‘totally reliable’ methods such as a
drip gauge (or dripstick in the case of the EMB-120) was not generally favoured by
operators because those methods were seen as time consuming and, for best
accuracy, necessitated the aircraft being on a level surface.
Two of the acceptable fuel quantity cross-check methods contained in the CAAP
involved comparing the change in electrical gauge readings with a quantity
determined independently, either from a fuel consumed indicator, or from a
refuelling installation. The operator of the EMB-120ER used the latter method
which, with regard to the subject occurrence, did not detect the fuel quantity error
before the flight to Jundee. In fact, neither method would ensure detection of a fuel
quantity error in cases where a gauge was under or over-reading by a constant
amount, or when there was a gradually increasing error.
The purpose of procedures for flight crew to follow to establish the quantity of fuel
on board was to provide assurance regarding the accuracy of the fuel quantity
indicating system and that the correct amount of fuel was on board for the flight.
Technical failures, such as fuel quantity indicating system malfunction, are
unavoidable, and occur from time to time. Flight crew procedures and checks are
intended to provide an additional layer in the safety system in the event of a
technical failure. For that layer to be effective, those procedures and checks must be
well designed, fully understood, and properly conducted by the users. In this
occurrence, none of those criteria were present. Unambiguous guidance regarding
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the importance of employing a ‘totally reliable’ method of establishing or validating
fuel quantity, and more robust flight crew procedures and practices, are required to
provide an appropriate level of assurance regarding fuel quantity measurement.
In addition to the occurrence involving the EMB-120ER, the ATSB is aware of
three other occurrences since January 2005 involving Australian-registered turbojet
or turboprop aircraft experiencing engine power loss due to similar fuel related
problems. They included a Fairchild Metro III on 23 September 2005 (ATSB
Report BO/200504768), a Boeing 747-338 on 5 February 2007 (ATSB Report
BO/200700368), and a Cessna C404 Titan on 18 October 2007 (ATSB Report AO-
2007-049). In each case, the practices used by the flight crew to establish fuel
quantity before flight did not detect erroneous fuel quantity indications. The
operators involved subsequently amended their procedures to include physical (e.g.
dripstick) checks as a mandatory part of the procedures for establishing the quantity
of fuel on board the aircraft.
It is possible that there are other examples among operators of aircraft where the
procedures used to determine the quantity of fuel on board the aircraft do not
provide an appropriate level of safety assurance. The CASA has initiated a project
to amend the CAAP guidance to provide better clarity and emphasis.
Aircraft handling
There were a number of facets of the crew’s performance that led to the
mishandling of the aircraft during the go-around:
• The crew did not detect the loss of fuel flow to the engine, or the engine power
loss. Neither crew member had been exposed to an engine power loss situation
on late final approach, either in training or during line operations.
• The crew did not keep the aircraft aligned with the runway during the approach.
It is probable that more positive input of the flight controls would have allowed
the aircraft to be kept aligned with the runway. However, the pilot flying was
likely to have manipulated the controls in the manner and to the extent that he
had become accustomed to during normal operations. In the asymmetric
situation that arose, in what was at the time a novel situation, such a technique
was unlikely to have been successful.
• The crew did not properly execute the go-around procedure. The behaviour of
the aircraft after the flight crew increased power to go around was, from their
perspective, abnormal and without reason or warning. It was likely that the
aircraft’s behaviour alarmed and focused each crew member to the extent that
they were unable to function effectively as a unit in the areas of decision making
and task sharing.
• There was a delay in the crew’s diagnosis of the situation. The aircraft was at or
near the limits of its performance envelope for a significant period after the go-
around was initiated.
The quality of the crew’s performance depended largely on their ability to recognise
the engine power loss, and to respond to the situation by functioning effectively as a
team.
The regulatory requirements for endorsement allow training solely in the aircraft, or
a mix of training in a flight simulator and the aircraft. For pilot in command, the
requirements were:
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• flying training was to include at least 5 hours flying time in conformity with
specified criteria involving general handling, takeoff, instrument flying,
asymmetric flight, and night flying, plus
• at least 50 hours flight time as pilot in command under supervision; or
• 25 hours flight time as pilot in command under supervision, and the successful
completion of an approved training course in an approved synthetic trainer.
In the case of a copilot, the syllabus was to include at least 3 hours flying time,
which was to cover takeoff, medium and steep turns, asymmetric flight, night flying
and general handling.
The EMB-120 type endorsement training the pilot and copilot had received, was
conducted solely on the aircraft and did not include any simulator training. For their
type endorsement, they each completed about 7 hours flight time, followed by 50
hours line training. The pilot in command completed a further 6 hours flight time
plus 83 hours in command under supervision for his command endorsement. In
terms of flight time, therefore, their training had exceeded the extant regulatory
requirements.
For important safety reasons, training in many sequences involving critical in-flight
emergency situations, can only be conducted in a flight simulator. Among the most
important of those situations are those involving an engine malfunction at a critical
stage of flight. The only means of safely conducting such training is in a flight
simulator.
Typically, EMB-120 endorsement training utilising a flight simulator involved
20 hours simulator time, plus 2 hours aircraft time. Because simulator training
exercises are conducted on a crew basis, trainees, in effect, receive 40 hours
simulator training time. Importantly, in addition to being exposed to the full range
of emergency situations, pilots are able to practice crew coordination in those
situations.
At the time of the occurrence, there was no EMB-120 flight simulator in Australia.
There were EMB-120 simulators in Europe and the US. However, significant time
and costs were involved for Australian operators to utilise those overseas facilities.
As a result, EMB-120 type training in Australia was conducted by each operator ‘in
house’, and solely on the aircraft. The only training for sequences that could not be
safely conducted in the aircraft during flight was via class room or cockpit
discussion.
The crew of XUE had never been exposed to an engine failure on late final
approach in the landing configuration. They were, therefore, confronted by a novel
situation on approach to Jundee and, arguably, were not equipped to respond
effectively in terms of either aircraft handling or crew coordination.
A similar argument would apply to many other possible emergency situations that
could occur in the EMB-120 aircraft, and other sophisticated multi-engine aircraft.
In that regard, the operator was probably no different to many other Australian
operators of turboprop aircraft, where similar deficiencies were likely to have been
present when flight crew training did not include any flight simulator training.
In March 2009, an EMB-120 flight simulator was commissioned in Melbourne,
Vic. Subsequently, under the guidance of CASA, all Australian EMB-120 operators
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began conducting flight crew endorsement, and some recurrent, training in the
simulator.
Since 1995, the ATSB has investigated four serious occurrences, in addition to the
subject occurrence, in which aircraft handling following actual or simulated engine
failures was a factor. Three of those occurrences, one of which involved two
fatalities, occurred during simulated engine failure training exercises. They were:
• Fairchild Industries Inc SA227-AC, VH-NEJ, Tamworth, NSW 16 September
1995 (Investigation Report 9503057),
• Fairchild Industries SA227-AC Metro III, VH-TAG, 33km ENE Canberra, ACT
21 November 2004 (Aviation Occurrence Report 200404589), and
• Beech 1900D Airliner, VH-NTL, Williamtown, NSW 13 February 2000
(Aviation Safety Report BO/2000000492)
The fourth occurrence involved Beech Aircraft Corporation King Air C90, VH-
LQH, Toowoomba, Qld on 27 November 2001, in which the pilot and three
passengers were killed following an actual engine failure on takeoff (Aviation
Occurrence Report 200507077).
There appears to be a gap between the quantity and quality of training that can be
achieved via the minimum endorsement requirements when simulator training is not
used, compared to that which can be achieved when a simulator is used. Given the
complexity of modern transport category aircraft and the benefits of simulator
training, the ATSB considers that in cases where a flight simulator is available in
Australia, then it should be mandated for endorsement training. The ATSB issued a
recommendation to CASA to take action to address that safety issue.
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THE AUSTRALIAN TRANSPORT SAFETY BUREAU
The Australian Transport Safety Bureau (ATSB) is an operationally independent
multi-modal bureau within the Australian Government Department of
Infrastructure, Transport, Regional Development and Local Government. ATSB
investigations are independent of regulatory, operator or other external
organisations.
The ATSB is responsible for investigating accidents and other transport safety
matters involving civil aviation, marine and rail operations in Australia that fall
within Commonwealth jurisdiction, as well as participating in overseas
investigations involving Australian registered aircraft and ships. A primary concern
is the safety of commercial transport, with particular regard to fare-paying
passenger operations.
The ATSB performs its functions in accordance with the provisions of the
Transport Safety Investigation Act 2003 and Regulations and, where applicable,
relevant international agreements.
Purpose of safety investigations
The object of a safety investigation is to enhance safety. To reduce safety-related
risk, ATSB investigations determine and communicate the safety factors related to
the transport safety matter being investigated.
It is not the object of an investigation to determine blame or liability. However, an
investigation report must include factual material of sufficient weight to support the
analysis and findings. At all times the ATSB endeavours to balance the use of
material that could imply adverse comment with the need to properly explain what
happened, and why, in a fair and unbiased manner.
Developing safety action
Central to the ATSB’s investigation of transport safety matters is the early
identification of safety issues in the transport environment. The ATSB prefers to
encourage the relevant organisation(s) to proactively initiate safety action rather
than release formal recommendations. However, depending on the level of risk
associated with a safety issue and the extent of corrective action undertaken by the
relevant organisation, a recommendation may be issued either during or at the end
of an investigation.
The ATSB has decided that when safety recommendations are issued, they will
focus on clearly describing the safety issue of concern, rather than providing
instructions or opinions on the method of corrective action. As with equivalent
overseas organisations, the ATSB has no power to implement its recommendations.
It is a matter for the body to which an ATSB recommendation is directed (for
example the relevant regulator in consultation with industry) to assess the costs and
benefits of any particular means of addressing a safety issue.
About ATSB investigation reports: How investigation reports are organised and
definitions of terms used in ATSB reports, such as safety factor, contributing safety
factor and safety issue, are provided on the ATSB web site www.atsb.gov.au.
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1 FACTUAL INFORMATION
1.1 History of the flight
On 26 June 2007 at 0639 Western Standard Time1, an Empresa Brasileira de
Aeronáutica S.A. EMB-120ER2 aircraft, registered VH-XUE, departed Perth, WA
on a contracted passenger charter flight to Jundee Airstrip. There were two pilots,
one flight attendant, and 28 passengers on the aircraft. At 0806, on final approach
for runway 08 (runway heading 082° M) at Jundee, the left engine sustained a total
power loss due to fuel starvation. The crew, unaware of the power loss, elected to
conduct a go-around at about 300 ft above ground level (AGL) because of
difficulties in maintaining alignment with the runway centreline. During the go-
around, the crew experienced significant difficulty in controlling the aircraft’s
attitude and airspeed and reported that the stick shaker3 activated on two occasions
before they regained control of the aircraft. The minimum altitude of the aircraft
during the go-around was about 50 ft AGL. After regaining control of the aircraft,
the crew diverted to Wiluna, which was located 42 km south-west of Jundee.
In subsequent interviews, the crew recalled that the departure, cruise, and descent
segments of the flight proceeded normally. The weather was fine, and the crew
elected to conduct a straight-in approach to Jundee. The copilot was the handling
pilot for the flight.
Table 1 provides the sequence of events associated with the approach and go-
around at Jundee. The information was obtained from the aircraft’s Digital Flight
Data Recorder (DFDR), and is supplemented from information obtained from
interviews with the crew (in italics). Additional information regarding warning and
alarm signals not recorded on the DFDR, but predicted from flight simulation
testing, is included [in square brackets].4 Because the aircraft’s electrical power was
operating for greater than 30 minutes after the occurrence, the cockpit voice
recorder contained no information of relevance to the occurrence.
1 The 24-hour clock is used in this report to describe the local time of day, Western Standard Time
(WST), as particular events occurred. Western Standard Time was Coordinated Universal Time
(UTC) + 8 hours.
2 The aircraft type is commonly referred to as a Brasilia.
3 A stick shaker is a mechanical device connected to the control yoke to warn the flight crew that
the aircraft is close to aerodynamically stalling.
4 The triggering of the various warning and alarm signals associated with the performance of the
number-1 engine was not recorded and it was not clear from the engine performance data when
the various warnings and alarms would have been displayed to the crew. At the request of the
Australian Transport Safety Bureau (ATSB), further investigation was undertaken by the aircraft
manufacturer in an EMB-120 flight simulator to determine the sequence and timing of caution and
warning activations that the crew should have received during the engine power loss under the in-
flight conditions that pertained at the time. That detail provided by the manufacturer is included in
the sequence of events table and denoted by underlined text. The warning and caution system is
described in Section 1.6.
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Table 1: Sequence of events5
Approx
local
time
Altitude,
Airspeed
Event
0754:51 Aircraft at top of descent (flight level 250).
0804:05 4,125 ft
198 kts
Flap 15 selected.
The crew reported that landing gear was selected down just
after the flap 15 selection.
0805:38 2,678 ft
142 kts
Flap 25 selected.
0806:05 2,493 ft
128 kts
Flap 45 selected. Torque for both engines increased from
below 20% to about 40%.
The crew reported that when the copilot called for flap 45,
the pilot in command called out that the reference speed for
the approach (Vref) was 111 kts. The operator’s procedures
required that flap 45 be used for all landings to unsealed
runways, which included Jundee (see Section 1.20.3).
0806:05 2,416 ft
124 kts
Flaps reached 45-degree position. Left engine torque
decreased to about 30%, right engine torque remained at
about 38%.
The crew reported that the aircraft was configured for
landing and that the ‘Before Landing’ checklist was
completed at about 700 ft AGL.
0806:16 2,344 ft
120 kts
Aircraft descended through 500 ft above runway elevation.
The crew reported that, at 500 ft AGL, the aircraft’s
enhanced ground proximity warning system (EGPWS)
sounded ‘500 feet’, in accordance with the normal
operation of that system. The copilot (as handling pilot)
called out ‘visual – continue’ in accordance with normal
procedures for a visual approach. The pilot in command
estimated that the wind at the time was 15 kts from 040
degrees. He also recalled noting around that time that the
left fuel gauge indicated about 200 kg and the right about
250 kg.
5 The listed time for each event is approximate only. However, the elapsed time between events is
based on recorded flight data. Airspeed figures refer to calibrated airspeed. Altitude figures were
adjusted from the recorded pressure altitude by considering the recorded altitude on landing at
Wiluna, and assuming that the air pressure at Jundee airstrip (1,845 ft above mean seal level
(AMSL)) and Wiluna (1,649 ft) was the same. Other parameters have been rounded to the nearest
whole number. Fuel flow was recorded in pounds / hour and was converted to kg / hour for the
purposes of this table. Landing gear position, thrust lever positions, fuel quantity and cockpit
alerts and cautions were not recorded.
- - 3
0806:24 2,279 ft
117 kts
Left engine torque increased to about 40%. Right engine
torque remained stable at about 38%.
The copilot recalled that shortly after the 500 ft call he
noticed a subtle change in the engine sound. He discerned
that, although the engine instrument displays were difficult
to read because of sun glare (see also Section 1.6.3 Engine
instrument panel), the engine parameters all appeared
normal and the left and right gauge pointers were
relatively symmetrical. The aircraft was on profile for the
approach, but as the airspeed was decreasing towards
Vref, he increased power to maintain speed.
The pilot in command recalled noting that the copilot
made a few control corrections for the crosswind and that
everything appeared normal.
0806:29 2,229 ft
114 kts
Left engine power loss. Left engine fuel flow decreased
from 207 kg / hour to 21 kg / hour 6 seconds later. Left
engine torque decreased from 42% and reached 0% 5
seconds later. Right engine fuel flow and torque remained
unchanged.
[Predicted events:
- amber FUEL light on multiple alarm panel (MAP)
- amber left LOW PRESS light on overhead fuel feed
panel
- left fuel pump ON lights on fuel feed panel began
flashing
- amber MASTER CAUTION light on glareshield panel
and associated single chime]
The crew did not recall seeing or hearing any cockpit
warnings or cautions before commencing the go-around
(at 0806:35). The copilot recalled that the aircraft began
to drift left of the runway centreline, and to slowly roll left.
He thought this may have been because the wind had
changed. He applied right control input to bring the
aircraft back to the centreline but did not observe any
response from the aircraft. He then increased the amount
of control input, but there still appeared to be no response
from the aircraft. The pilot in command recalled that the
aircraft was drifting left of the runway centreline at this
time.
0806:33 2,141 ft
110 kts
Aircraft descended through 300 ft above runway elevation.
[Predicted events:
- amber ELEC light on MAP
- amber left GEN BUS OFF light on overhead electrical
panel
- amber MASTER CAUTION light on glareshield panel
and associated single chime]
- - 4
The crew recalled that the copilot advised the pilot in
command that he could not bring the aircraft back to the
centreline and he suggested that they go around. The pilot
in command assessed that the approach was not stabilised
at 300 ft in accordance with the operator’s stabilised
approach criteria (see Section 1.20.3), so he called for a
go-around.
0806:35 2,130 ft
110 kts
Go-around initiated. Right engine torque began to
increase. Aircraft began to roll left.
The crew recalled that, as the copilot advanced the engine
power levers at the commencement of the go-around, the
aircraft yawed and rolled left ‘aggressively’ before the
copilot could complete the standard call (‘Going round,
set power, flaps 15; see Section 20.2). The copilot applied
right rudder and aileron but was unable to control the
aircraft. He informed the pilot in command that he was
unable to hold the control inputs. The pilot in command
placed his hands on the control yoke and his feet on the
rudder pedals and assisted the copilot.
0806:38
to
0806:39
[Predicted events:
- red EEC(engine electronic control) 1 light on glareshield
panel
- white MANUAL light on overhead EEC panel
- red MASTER WARNING light on glareshield panel
- triple chime followed by ENGINE CONTROL voice
message
- red OIL PRESS 1 light on MAP
- red master WARNING light on glareshield
- triple chime followed by ‘OIL’ voice message]
0806:39 2,084 ft
109 kts
Right engine torque reached 125%. Roll attitude 7 degrees
left. Aircraft heading started to diverge left from 079° M.
At some stage during the go-around, the crew noticed that
a red master warning caption OIL PRESS (oil pressure)
for engine number 1 (the left engine) had illuminated and
an amber master caution for FUEL had illuminated on the
MAP.
0806:42 2,065 ft
107 kts
Altitude temporarily stabilised at about 220 ft above
runway elevation (until 0806:39). Roll attitude 13 degrees
left. Heading 073° M.
0806:48 2,065 ft
103 kts
Right engine torque reached 150%. Two seconds later it
decreased, reaching 130% by 0806:33. It remained in the
range 125 to 130% until 0807:47. Roll attitude 16 degrees
left. Heading 061° M.
0806:59 2,085 ft
96 kts
Flap 25 selected. Roll attitude 34 degrees left. Heading
014° M.
- - 5
After deciding that aircraft control was stabilised, the
copilot called for the flaps to be retracted to the ‘flaps 25’
position.
The pilot in command reported that he selected flap 25
after confirming that the copilot had control of the
aircraft.
0807:00 2,068 ft
97 kts
Altitude started to decrease again. Roll attitude 35 degrees
left. Heading 004° M. Pitch attitude had reached 9 degrees
nose-up.
0807:02 2,053 ft
100 kts
Roll attitude reached maximum value (40 degrees left).
Heading 346° M. Pitch attitude 1 degree nose-up.
The crew recalled that the stick shaker activated twice
during the go-around, and that each time they slightly
reduced the control yoke back pressure to remove the
warning. The EGPWS warning ‘too low terrain’ also
sounded at some time during the go-around.
0807:05 1,990 ft
103 kts
Flaps reached 25° position. Roll attitude 37 degrees left.
Heading 319° M.
0807:10 1,898 ft
105 kts
Aircraft reached lowest altitude, equivalent to about 50 ft
above runway elevation. Altitude increased in subsequent
seconds. Roll attitude 14 degrees left. Heading 285° M.
Pitch attitude 9 degrees nose-up.
0807:20 2,009 ft
95 kts
Airspeed reached lowest recorded value (95 kts). Roll
attitude 7 degrees left. Heading 272° M. Pitch attitude
reached highest value (12 degrees nose-up).
0807:56 2,089 ft
103 kts
Roll angle stabilised at about wings-level. Pitch attitude 6
degrees nose-up. Heading stabilised 198° M.
0809:30 2,539 ft
111 kts
Flap 15 selected.
0809:41 2,597 ft
117 kts
Flap zero selected.
The crew recalled that after raising the flaps the landing
gear was selected up.
0810:55 3,407 ft
134 kts
Left engine shutoff selected.
After the landing gear was retracted, the crew turned their
attention to the warnings they had noted earlier. They
recalled that, in addition to the OIL PRESS and FUEL
warnings, the amber left LOW PRESS light on the
overhead fuel feed panel was illuminated, the white lights
for both left electric boost pumps were ON, and the
number-1 white EEC light was on. The fuel gauges were
indicating just over 200 kg per side. The crew then
- - 6
completed the checklist actions for an engine failure in
flight. They reported that when the left engine condition
lever was placed in the feather position, there was a
significant improvement in aircraft performance.6
0810:57 3,421 ft
134 kts
[Predicted events:
- ELEC amber light illuminated on MAP,
- left AUX GEN OFF BUS amber light illuminated on
electrical panel (on overhead panel) and
- respective master CAUTION amber light on glareshield
panel illuminated with its associated single chime.
The auxiliary generators are also driven by the propeller
gearbox and they are disconnected when the respective
propeller speed is 70% or lower.]
0811:06 3,539 ft
135 kts
[Predicted events:
- amber HYD light on MAP
- amber left MAIN PUMP LOW PRESS on overhead
hydraulic panel
amber MASTERCAUTION light on glareshield panel with
associated single chime]
0812:28 3,603 ft
167 kts
Press-to-talk switch activated.
The crew reported that they levelled the aircraft at 3,400 ft
(the lowest safe altitude). Because Wiluna was close by,
the aircraft was heading in the direction of Wiluna, and
the runway at Wiluna was sealed, the crew decided to land
there. The pilot in command transmitted a PAN7
emergency message to air traffic control, advising an
engine failure and that they were diverting to Wiluna.
0818:31 Aircraft landed at Wiluna.
The aircraft’s flight log indicated that there was 1,190 kg of fuel on board the
aircraft prior to the departure from Perth. That amount included 680 kg residual fuel
on board from the previous flight and 511 kg of fuel added immediately before the
flight. After shutting down the aircraft at Wiluna, the crew recorded that the fuel
gauges indicated there was 370 kg fuel remaining.
Following the occurrence, the operator dispatched engineers to examine the aircraft.
They reported that the cockpit fuel quantity indicators displayed 300 kg (left tank)
6 The automatic propeller feathering system did not activate unless three conditions were met.
Those were that the torque on both engines was greater than 62 percent, both power lever angles
were greater than 62 degrees, and the automatic feathering system was ARMED.
7 Radio code indicating uncertainty or alert, general broadcast to widest area but not yet at level of
MAYDAY.
- - 7
and 150 kg (right tank). A physical check of both tanks revealed that the left tank
contained no fuel, and the right tank contained 150 kg of fuel.
1.2 Injuries to persons
There were no injuries to any of the crew or passengers.
1.3 Damage to aircraft
Because the recorded flight data indicated that the engine limitations may have been
exceeded during the go-around, the engine manufacturer suggested that the
reduction gear box of the right engine be removed and overhauled. That action was
subsequently taken by the aircraft operator.
1.4 Personnel information
1.4.1 Pilot in command
The pilot in command had 3,040 total flying hours. He obtained a Commercial Pilot
(Aeroplane) Licence on 12 October 2000 and an Air Transport Pilot (Aeroplane)
Licence on 21 July 2005. Prior to commencing employment with the operator, he
had 746.4 hours as pilot in command of multi-engine aircraft and no previous
turbine-engine aircraft experience.
On 21 August 2006, the pilot in command obtained an EMB-120 copilot
endorsement with the operator, which involved 7.6 hours flight time. He was
cleared for line operations as a copilot on 20 September 2006 (after 50 hours
supervised flight time), and logged a total of 260.8 hours as a copilot. He obtained a
command endorsement from the operator on 19 January 2007, which involved 6.2
hours flight time. He initially did not pass a clearance to line check after 50 hours in
command under supervision. The check pilot noted no problems with his
knowledge of systems or procedures, but believed he required further experience to
increase his confidence. He passed the second check after 83.8 hours with no
problems noted. After being cleared for line operations as pilot in command on 19
February 2007, the pilot in command completed 298.0 hours in that role. His total
experience on the EMB-120 at the time of the occurrence was 648.8 hours.
Prior to completing his command endorsement, his last proficiency check was the
renewal of his multi-engine command instrument rating on 15 December 2006.
Management and check and training pilots advised that they had no concerns
regarding the pilot in command’s ability.
The operator’s Flight Standards Manual stated that all new crew members had to
complete a crew resource management (CRM) theory course ‘as soon as
practicable’, and that all crew members ‘shall receive refresher training in this
subject within every two years’. The pilot in command had not completed a CRM
course during his time with the operator. He had completed a Bachelor of Aviation
degree in July 2003, which included a subject on human factors.
The pilot in command stated that he was well rested and in good health at the time
of the occurrence. He had conducted 3.9 hours flying on the day prior to the
- - 8
occurrence, with his duty time finishing at 1300. He conducted no duties for the
operator on the previous 10 days.
1.4.2 Copilot
The copilot had 1,618.3 hours total flying hours. He obtained a Commercial Pilot
Licence (Aeroplane) on 2 January 2003. Prior to commencing employment with the
operator, he had no previous turbine-engine aircraft experience and 25.5 hours as
pilot in command of multi-engine aircraft.
On 21 April 2005, he obtained an EMB-120 copilot endorsement with the operator,
which involved 6.7 hours flight time. He was cleared for line operations as a copilot
on 17 May 2005 (after 50 hours supervised experience). He had a total of 1,356.1
hours as a copilot on EMB-120 aircraft.
The copilot’s last aircraft proficiency check was completed on 10 May 2007.
Management and check and training pilots advised that they had no concerns
regarding the copilot’s ability, and that he was above average as a handling pilot.
The copilot provided EMB-120 ground school training as part of his employment.
The copilot completed a 1-day CRM course with the operator on 12 October 2005.
In late 2004, prior to commencing employment with the operator, he completed
human factors and CRM training as part of a multi-crew training program with
another airline. That training included a series of nine line orientated flight training
(LOFT) style exercises in a generic simulator based on a large passenger jet aircraft.
The sessions had an emphasis on areas such as decision-making, communication
skills, and threat and error management.
The copilot stated that he was well rested and in good health at the time of the
occurrence. He conducted no duties for the operator during the previous 4 days.
1.5 Aircraft information
The EMB-120ER8 was a twin turboprop engine aircraft with a maximum take-off
weight of 11,990 kg. The aircraft was certified in the transport category for the
carriage of passengers and freight. In the passenger role, it had a maximum seating
capacity of 30 passengers. It was powered by two Pratt & Whitney Canada
PW118 turboprop engines.
At the time of the occurrence, there were 22 EMB-120 aircraft on the Australian
civil aircraft register.
VH-XUE was manufactured in 1989 and placed on the Australian register in 1995.
According to the maintenance records, the aircraft had completed 22,597 operating
hours and 26,044 cycles at the time of the occurrence.
1.5.1 Instrument panel layout
The main cockpit instrument panel is depicted in the schematic at Figure 1.
8 The letters ER denote an ‘Extended Range’ version of the EMB-120 aircraft.
- - 9
Figure 1: Schematic of EMB-120 instrument panel
An overhead panel (Figure 2) included control switches and indicators for various
aircraft systems, including the engine control (A), fuel (B), electrical (C), and
hydraulic (D) systems.
Figure 2: Overhead control panels
Note: This edge adjacent to front of cockpit roof
1.5.2 Cockpit alarm and indications
There were alarm and indication lights in the cockpit that provided information on
failures identified by the legend inscribed thereon, or by a combination of that
legend and the adjacent panel inscriptions. Legends were readable only when
- - 10
illuminated and were coloured red or amber according to the seriousness of the
failure and the degree of urgency attached to the crew’s response as follows:
• Red – a failure or malfunction requiring immediate action and representing a
hazard to the aircraft that could lead to an unsafe flight condition (that is, a
‘warning’).
• Amber – a failure not requiring immediate action (that is, a ‘caution’).
The alarm and indication lights remained illuminated as long as the fault persisted.
Green and white indication lights provided information regarding the status of some
aircraft systems as follows:
• Green – indicated normal operation for systems where a positive indication of
correct functioning was desirable.
• White – indicated normal operation of systems not normally required, or of
standby system operation when the main system had failed.
The multiple alarm panel (MAP) consisted of a panel of captions to alert the crew
to failures of specific components and systems within the aircraft. The panel layout
was as shown in Figure 1, with the red warning captions occupying the central four
columns of the panel.
When a fault occurred, the appropriate caption began flashing. Additionally, the red
WARNING or the amber CAUTION lights (as appropriate) on the instrument panel
in front of each control position (Figure 1) also began flashing. The aircraft was
also equipped with an aural alert system that included synthesised voice messages,
discrete tones, and chimes. Three chimes (Level 3) sounded in the event of a
situation that required immediate action by the crew. One chime (Level 2) sounded
when immediate crew awareness and subsequent crew action was required. A Level
2 chime took priority over voice messages. For example, in the case of an electronic
engine control failure, the crew would hear three chimes followed by an ‘engine
control’ voice message. Low engine oil pressure would generate a Level 3 chime,
followed by an ‘oil’ voice message.
Checks following the occurrence confirmed that the various alarm and warning
systems on the aircraft were functioning normally.
1.5.3 Engine instruments
Figure 3 shows the two columns of engine instruments for the left and right
engines. The instruments were, from top to bottom:
• intra-turbine temperature
• percentage engine torque,
• percentage propeller speed
• low pressure and high pressure spool speed indication
• a combined gauge showing oil temperature and pressure.
All gauges, except for oil, displayed information in analogue and digital formats.
The torque gauges were highlighted by a yellow border.
- - 11
Figure 3: The two columns of five instruments for numbers 1 and 2 engines
(dark shading)
1.5.4 Indications in the event of fuel starvation
The manufacturer advised that in the event of fuel starvation, a fuel low pressure
condition would exist and cause the fuel low pressure light to commence flashing.
The sequence of events would be as follows:
LOW PRESS and Fuel Pump ON lights flashing on the fuel panel (located
in the overhead panel).
FUEL light illuminated on the Multiple Alarm Panel (light is amber).
CAUTION light flashing (on the glareshield panel and cancellable through
the ALARM CANCEL SWITCH, caution light is accompanied with a
single chime aural alarm)
Due to the engine starvation a shutdown will occur, with the following
engine parameters reducing:
o torque indication
o fuel flow indication
o low pressure spool speed indication (NL)
o high pressure spool speed indications (NH)
o intraturbine temperature indication (T6)
o propeller speed indication (NP)
o oil pressure indication.
- - 12
When oil pressure reaches 40 psi, an OIL PRESS 1 or OIL PRESS 2 light
will illuminate on the MAP (light is red) and a WARNING light will flash
on the glareshield panel (cancellable through the ALARM CANCEL
SWITCH).
The manufacturer advised that there would also be other indications and warnings
associated with the electrical and hydraulic systems, and the EEC as follows:
• When high pressure spool speed fell below 50%, the ELEC amber light on the
MAP and the left GEN OFF BUS amber light would illuminate on the overhead
electrical panel. The respective master CAUTION amber light on the glareshield
panel would also illuminate, accompanied by a single chime.
• When high pressure spool speed fell below 25%, the EEC 1 red light on the
glareshield panel and the MANUAL white light on the overhead EEC panel
would illuminate. An associated master WARNING red light on the glareshield
panel would also illuminate, accompanied by a triple chime and an ENGINE
CONTROL voice message.
• When propeller speed dropped below 70%, the ELEC amber light on the MAP,
and the left AUX GEN OFF BUS amber light on the overhead electrical panel
would illuminate. The respective master CAUTION amber light on the
glareshield panel would also illuminate, accompanied by a single chime.
• When hydraulic pressure fell below 1,500 psi (there is a hydraulic pressure
gauge on the overhead panel), the HYD amber light on the MAP, the left MAIN
PUMP LOW PRESS amber light on the overhead hydraulic panel would
illuminate. The respective master CAUTION light on glareshield panel would
also illuminate, accompanied by a single chime. (As the electric hydraulic pump
was probably on AUTO position (the normal position during flight), the
electrical hydraulic pump probably provided hydraulic pressure for the green
hydraulic system, with its associated ELEC PUMP white light illuminated on
the hydraulic panel.)
1.5.5 Fuel quantity indicating system
There were inboard and outboard fuel tanks in each wing of the aircraft. The tanks
were interconnected and acted as a single reservoir. The fuel systems for each wing
were identical and independent. The aircraft operating manual stated that the
aircraft’s maximum fuel capacity was 2,622 kg (3,340 L), including 22 kg (28 L) of
unusable fuel. Those figures were based on an average fuel density of 0.785 kg/L.
The quantity of fuel in the aircraft’s tanks was measured by an electrical
capacitance indicating system. Each wing was fitted with six capacitive fuel sensor
units or probes. There were four fuel sensor probes in each outboard tank and two
in each inboard tank. Capacitance measured by each probe varied depending on the
length of the probe that was immersed in fuel. The system was designed so that
total tank capacitance (and thus indicated fuel quantity) was not affected by changes
in aircraft attitude.
A fuel management panel (Figure 4) was positioned in the centre section of the
cockpit instrument panel. The panel featured fuel quantity indicators and fuel flow
indicators for the left and right fuel systems.
- - 13
Figure 4: Fuel management panel
The fuel quantity indicators displayed, in 100-kg units, the total fuel quantity in the
corresponding wing. The quantity indication was compensated for temperature and
fuel density. The indicators displayed zero when there was no usable fuel
remaining.
The fuel flow indicators displayed the fuel flow, in kg per hour, for each engine.
The fuel flow indicators were independent of the fuel quantity indicating system.
1.5.6 Fuel totaliser
A fuel totaliser display, positioned immediately above the fuel quantity indicators,
displayed digitally the total amount of fuel used or the total amount remaining,
depending on the mode of operation selected by the flight crew as follows:
• operation of the FCTN button alternated the display between FU (Fuel Used)
and FR (Fuel Remaining)
• operation of the PULL TO SET knob in the FU mode reset the fuel used display
to zero
• operation of the PULL TO SET knob in the FR mode copied the fuel quantity
indicated by the Fuel Quantity Indicators
• fuel remaining could be set manually by rotating the PULL TO SET knob. A
clockwise rotation increased the indicated fuel remaining and counter-clockwise
rotation decreased the indicated fuel remaining.
In the fuel used function, the displayed value was based solely on inputs from the
fuel flow transmitters since the totaliser had been last reset. In the fuel remaining
function, the displayed value was the difference between the initial total fuel on
board when the totaliser was last reset (obtained from the fuel quantity indicating
system) and the fuel used. Therefore, other than when the fuel totaliser was reset,
- - 14
the displayed quantity was determined in a manner which was independent of the
fuel quantity indicating system.
The APU was not equipped with a fuel flow transmitter, but APU fuel burn was
estimated from discrete signals. The aircraft maintenance manual (Section 28-43-
00, page 3) included the following information:
C. When applicable, APU fuel consumption is determined by means of three
discrete signals sent by the APU control switches (Ref. 49-74-00), which
cause the totalizer to add predetermined rates to the fuel consumed. When the
APU operates without a load, the signal corresponds to a 45 pph consumption
(20.4 kg/hr). Operation with the generator on corresponds to a 53 pph (24
kg/hr) consumption. Operation with bleed air corresponds to a 90 pph (40.8
kg/hr) consumption, and operation with generator on and bleed air
corresponds to a 98 pph (44.5 kg/hr) consumption.
Note: The APU fuel burned from the time the APU was started (usually
maintenance action upon aircraft power up) to the time the fuel totaliser was reset
(usually pilot action while performing the 'before start' procedures) will not be
computed in the fuel consumed for that flight leg on the fuel totaliser. The aircraft
operator used 60 kg/hr as a standard allowance for APU fuel burn.
1.5.7 Dripless measuring sticks
The aircraft was also equipped with dripless measuring sticks (sometimes referred
to as ‘magna sticks’) that enabled the manual measurement of the fuel quantity in
each wing. There were three dripless measuring sticks for each outboard tank, and
one for each inboard tank. The dripless stick system consisted of a magnet floating
on the surface of the fuel in the tank and a calibrated stick. The sticks were
unlocked via access points on the lower surface of the wing and were allowed to
lower until the floating magnet attracted the upper end of the stick (Figure 5). That
enabled the level of the fuel to be determined.
A conversion table carried on the aircraft was used to convert the reading on the
stick to a fuel tank quantity in kilograms. Accurate quantity measurement using the
dripless sticks required the aircraft to be laterally level.
Dripless measuring sticks, along with other physical check methods, are the most
reliable means of establishing fuel quantity.
- - 15
Figure 5: A dripless stick in the lowered position, indicating 2.8 on the
measurement scale
1.5.8 Fuel low-level warning system
The EMB-120 was not equipped with a fuel low-level warning system, nor was it
required by regulation. The aircraft manufacturer advised that the EMB-120 was
certified in accordance with ANAC (Agência Nacional de Aviação Civil),
complying with RBHA (Regulamento Brasileiro de Homologação Aeronáutica)
Part 25, which did not require the incorporation of a fuel low-level warning system.
The equivalent US Federal Aviation Regulation (FAR) Part 25 also did not require
the incorporation of a fuel low-level warning system.
As a result of recent occurrences involving other turboprop and turbojet aircraft,
three European national investigation agencies9 have issued recommendations for
aircraft certification standards to be enhanced to require fuel low-level warning
systems on all such aircraft, and to ensure that such systems where fitted are
independent of the fuel quantity indicating system. Further details on those
recommendations are provided in Appendix B.
1.5.9 Fuel system maintenance history
According to the aircraft maintenance documentation, on 21 August 2006, a fuel
tank wiring inspection revealed a damaged section at the left wing tip. That damage
9 Those agencies included the Irish Air Accident Investigation Unit (AAIU), the Italian Agenzia
Nazionale per la Sicurezza del Volo (ANSV), and the UK Air Accident Investigation Branch
(AAIB).
- - 16
was repaired on 1 September 2006. On 11 September 2006, the aircraft underwent
maintenance action to repair damaged fuel quantity indicating system wires at the
inboard probe in the left tank. The aircraft underwent a maintenance check on
5 October 2006 that included the calibration of the fuel quantity indication system.
On 22 October 2006, an inspection of the fuel quantity wiring harness was carried
out. No defects were reported. Between that date and the occurrence, only one fuel
quantity indication system defect was recorded. That occurred on 15 February
2007, and referred to the fuel totaliser not indicating the correct quantity when
reset. The fault was rectified by replacing the totaliser.
The aircraft’s flight logs noted an event on 6 December 2006 when 280 kg of fuel
was removed from the left wing tank. Subsequently, the same amount was added to
the left tank. That amount corresponded to half of the recorded total fuel quantity
on board the aircraft at the time (580 kg). The reason for the apparent defueling of
the left wing was not stated on the relevant flight log; nor was any detail contained
in the aircraft maintenance records.
1.5.10 Examination of the fuel quantity indicating system
When the aircraft was examined after the occurrence, the left fuel tank was empty,
while the fuel quantity indicator displayed 300 kg. A check of the overall
capacitance of the left fuel quantity indicating system revealed that it was out of
limits on the low side. The capacitances of all left side probes (while still installed)
were also out of limits on the low side. When the left side probes were removed and
bench tested, all tested correctly except probe number-6 (the left outboard probe),
which showed similar below-limits capacitance as it did while installed. After a
replacement probe was fitted in the number-6 position, the total system capacitance
returned to the correct value.
The right fuel quantity indicating system was checked and confirmed serviceable.
A visual inspection of the left wing indicating system wiring harness in situ did not
reveal any abnormality. The harness was subsequently removed from the aircraft
and inspected under magnification. That inspection revealed several areas of
damage to the loom, particularly on the number-6 probe wires (Figure 6). There
was evidence that those wires had been short circuiting to the metal airframe
structure inside the wing tank and also between the AC supply, DC positive and DC
negative wires. That caused intermittent and hard short circuits and arcing, leading
to the failure of two diodes on the number-6 probe. There was no record that the
loom had been removed from the aircraft since its manufacture in 1989.
The aircraft manufacturer advised that it was aware of only one other instance of
fuel quantity indicating system malfunction in EMB-120 aircraft (see also Section
1.13.1). That malfunction occurred in September 2001 and involved the right fuel
quantity indicator reading fluctuating approximately 300 pounds (136 kg). The
problem was traced to a faulty cannon plug on the back of the indicator.
- - 17
Figure 6: Wiring loom showing exposed wire and abraded insulation layers
1.6 Meteorological information
1.6.1 Local weather conditions
The Bureau of Meteorology (BoM) advised that a high pressure system was
directing a north to north-east airflow across the occurrence area. The Bureau also
advised that there were no weather observations at Jundee. However, the 0900
synoptic observation from Wiluna showed temperature as 12° C and a northerly
wind at 2 kts. The weather was described as ‘cloud not observed or not observable’.
The crew’s report of the weather was consistent with this information.
1.6.2 Sun position information
According to the Geoscience Australia website, at 0806 on 26 June 2007, the sun’s
position was 055° T in azimuth (053° M) and 15° in elevation. Consequently,
during the approach to Jundee, the sun was located about 24° left of the aircraft’s
heading and 15° above the horizon.
1.7 Aids to navigation
Not relevant to the circumstances of the incident.
1.8 Communications
Communications between the aircraft and air traffic control during the flight were
normal.
- - 18
1.9 Aerodrome information
Jundee Airstrip was privately operated. It consisted of a 2,095 m long gravel
runway 08/26, which included a 200 m sealed section at each end. The runway
elevation was 1,845 ft above mean sea level (AMSL). The apron area was adjacent
to the runway 26 threshold. The terrain in the vicinity of the airstrip was reported to
have been flat, with vertical obstacles limited to a few metres.
Wiluna Airstrip was located 42 km south-west of Jundee. It had a sealed runway
15/33, which was 1,811 m long, and an unsealed runway 03/21, which was 1,219 m
long.
1.10 Flight recorders
VH-XUE was fitted with a flight data recorder (FDR) and a cockpit voice recorder
(CVR) as required by Australian regulations.
The CVR was an L-3 Communications Aviation Recorders model A100S, which
was capable of recording four channels of audio for a duration of 30 minutes. The
CVR was successfully downloaded and the recorded information recovered. It was
found that information relating to the incident had been overwritten by ground
running carried out by engineers engaged in fault finding activity on the aircraft
after the incident.
The FDR was an L-3 Communications Aviation Recorders model F1000, which
was capable of recording a minimum of 25 hours of aircraft operation. The L-3AR
model F1000 FDR utilises a method of data compression which can result in more
than 25 hours of information being recorded. The FDR was successfully
downloaded.
The recovered data included a landing and 19 complete sectors, about 39 hours 12
minutes of aircraft operation, which included the incident flight and the subsequent
diversion to Wiluna. The incident flight was plotted and the related data analysed. It
was noted that the propeller RPM recording system exhibited unusual
characteristics, indicating a possible problem with the transducer or wiring
connecting the transducer to the flight data acquisition unit.
A plot of the FDR data for the final approach and go-around is at Figure 7. The
parameters displayed include, with respect to aircraft systems, flap angle, propeller
and torque values for both engines and engine condition lever position. The
displayed aircraft performance values include pitch and roll attitude, magnetic
heading, pressure altitude and airspeed.
- - 19
Figure 7: Recorded FDR parameters for approach and go-around
- - 20
1.11 Tests and research
1.11.1 Flight simulator replication of the occurrence by other pilots
At the time of the occurrence involving VH-XUE, another Australian EMB-120
operator had arranged for two of its pilots to attend EMB-120 simulator training
overseas.10 That operator was approached by a Civil Aviation Safety Authority
(CASA) representative to have its pilots replicate the VH-XUE event in the
simulator. That exercise was subsequently undertaken.
The pilots involved reported that a scenario was developed where an engine was
failed on late final approach with full flap selected and the landing gear down. A
missed approach was then initiated. One hundred per cent torque was applied, flap
15 was selected, and the propeller was not feathered. The pilots found that they
could not maintain control of the aircraft and the simulator ‘crashed’ after turning
through about 90 degrees. Similar results were obtained using 110 and then 120%
torque. A successful but ‘untidy’ go-around, during which the stick shaker operated
a number of times, was achieved when they used torque levels similar to those they
had been told were used by the crew of VH-XUE.
The pilots involved also reported that they attempted to continue the approach after
the engine had ‘failed’. They found that the aircraft could rapidly lose alignment
with the runway to the extent that a landing could not be achieved. They found that
with a windmilling propeller, flap 45, and landing gear down, greater than 90% per
cent torque was required to maintain airspeed and the approach path. Further, there
was little change in engine noise when the engine failure was initiated. The first
noticeable indication they received was a single alert chime followed by the
illumination of the ELEC and MAIN GEN OFF BUS captions on the MAP.
The pilots added that their responses in the simulator were against the background
of knowing that an engine was going to ‘fail’. They considered that detecting and
responding to an actual and unexpected engine failure situation would have been
considerably more challenging.
1.12 Fuel quantity measurement processes
1.12.1 Regulatory requirements and guidance
Civil Aviation Regulation (CAR) 234(1) stated:
(1) The pilot in command of an aircraft must not commence a flight within
Australian territory, or to or from Australian territory, if he or she has
not taken reasonable steps to ensure that the aircraft carries sufficient
fuel and oil to enable the proposed flight to be undertaken in safety.
10 At the time of the occurrence, there was no EMB120ER simulator in Australia. Local operators
who wished to undertake simulator training had to travel to facilities in the US or Europe.
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(2) An operator of an aircraft must take reasonable steps to ensure that an
aircraft does not commence a flight as part of the operator’s operations if
the aircraft is not carrying sufficient fuel and oil to enable the proposed
flight to be undertaken in safety.
Civil Aviation Order (CAO) 20.2 (Air Service Operations – Safety Precautions
Before Flight) provided further requirements. As of 8 May 2006, it stated:
6.1 The operator of an aircraft having a maximum take-off weight of more
than 5700 kg and engaged in commercial operations must ensure that the
operations manual contains instructions and procedures for the pilot in
command of the aircraft to verify the quantity of fuel on board the
aircraft before flight.
Note: See Airworthiness Bulletin 28-002 for advice on instructions and
procedures that may be adopted to verify the quantity of fuel on board an
aircraft before flight.
Airworthiness Bulletin (AWB) 28-002, dated 15 May 2006, stated:
Unless assured that the aircrafts tanks are completely full, or a totally reliable
and accurately graduated dipstick, sight gauge, drip gauge or tank tab reading
can be done, the pilot should endeavour to use the best available fuel quantity
cross-check prior to starting. The cross-check should consist of establishing
the fuel on board by at least two different methods, such as:
1. Check of visual readings (tab, dip, drip, sight gauges against electrical
gauge readings); or
2. Having regard to previous readings, a check of electrical gauge or visual
readings against fuel consumed indicator readings; or
3. After refuelling, and having regard to previous readings, a check of
electrical gauge or visual readings against the refuelling installation
readings; or
4. Where a series of flights is undertaken by the same pilot and refuelling is
not carried out at intermediate stops, cross-checks may be made by
checking the quantity gauge readings against computed fuel on board
and/or fuel consumed indicator readings, provided the particular aircraft’s
fuel gauge system is known to be reliable.
Civil Aviation Advisory Publication (CAAP) 234-1(1) was revised in November
2006 to provide similar guidance as that contained in AWB 28-002.11
Prior to May 2006, CAO 20.2 included as regulatory requirements the advisory
cross check methods included in AWB 28-002.12 As part of a regulatory change
process, CASA stated that those requirements appeared to be unique to Australia. It
proposed changing the requirements to be consistent with the outcome-based rules
11 In late 2007, AWB 28-002 was withdrawn as a listed CASA publication. The first method of cross
check listed in the CAAP was worded as follows: ‘Check of visual readings (tab, dip, drip, sight
gauges) against fuel consumed indicator readings’.
12 Prior to May 2006, CAO 20.2 also stated that the cross-check procedures ‘must be specified by
the operator, together with an allowable discrepancy which must not exceed 3 per cent of the
higher amount’.
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of the US Federal Aviation Administration (FAA) and the European Aviation
Safety Authority (EASA). Accordingly, CAO 20.2 was amended on 8 May 2006.
1.12.2 Operator’s fuel quantity measurement procedures
The operator published fuel quantity checking procedures in its Flight Operations
Manual and its Brasilia Flight Operations Manual.
The Flight Operations Manual stated:
Aircraft with a MTOW exceeding 5700 Kg shall not commence a flight
unless the PIC [pilot in command] has ensured that the fuel quantity on board
has been confirmed by use of two separate cross check methods. The
maximum discrepancy between the two methods shall be the quantity defined
in the aircraft type operations manual…
The Brasilia Flight Operations Manual stated:
Prior to flight, a check of the total fuel on board must be carried out by two
separate methods. The difference between these two checks shall be less than
60 kg.
Acceptable methods of cross checking fuel for the [Operator’s] Brasilia are:
• Check of magna stick readings against electrical gauge readings; or
• Having regard to previous readings, a check of electrical gauge or magna
stick readings against fuel consumed indicator readings; or
• After refuelling, and having regard to previous readings, a check of
electrical gauge or magna stick readings against the refuelling installation
readings; or
• Where a series of flights is undertaken by the same pilot and refuelling is
not carried out at intermediate stops, cross-checks may be made by
checking the quantity gauge readings against computed fuel on board and/or
fuel consumed indicator readings, provided the particular aircraft’s fuel
gauge system is known to be reliable.
The APU burn allowance of 58 kg per hour may be considered when making
the fuel cross check.
When using the magna sticks, significant variations may occur if the aircraft
is not level. A check of level may be made on the EADI [electronic attitude
display indicator]. A pitch of ± 2° is allowable. The recommended practice
when using the magna sticks is the [sic] take the reading then immediately
return the stick to the locked position.
The operator reported that, prior to May 2006, its procedures included 3° as the
maximum allowable discrepancy. When the amended CAO was issued in May
2006, the operator changed the allowable discrepancy for the EMB-120 to 60 kg.
The rationale for that change was that, while 60 kg was less than 3% at maximum
and higher fuel quantities, it was close to 3% at the quantities that were used in
most day-to-day operations. The operator advised that the change was reported to
CASA and incorporated into the operator’s manual.
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1.12.3 Use of flight logs
The operator provided flight crew with a flight log for recording aircraft operational
data for each day’s operations. The ‘fuel load’ section of the log contained columns
for recording fuel quantity information for each flight (Figure 8).
Figure 8: Fuel Load section from a sample flight log
As shown in Figure 8, there were four columns in the flight log for recording fuel
quantity information:
• total fuel quantity at departure
• burn (or fuel used during a flight)
• residual (or fuel remaining at the end of a flight)
• added (or fuel added prior to the next flight).
The Flight Operations Manual included the following guidance on use of the flight
log:
The figure placed in the ‘Fuel Total’ column of the Flight Log Form shall be
the fuel total as read from the fuel gauges (corrected if necessary), not the
calculated fuel total.
Crews shall consistently check the fuel burns against the residual fuel figure
for accuracy on every sector.
Fuel on board gauge readings are to be checked prior to departure by adding
the fuel quantity uplifted, as per the release note, to the fuel quantity
remaining at the end of the previous flight which has been recorded on the
Flight Log.
In addition to the flight crew, six other company EMB-120 pilots were interviewed,
including the EMB-120 fleet manager and a training-and-checking pilot. In terms of
how flight logs were completed, those pilots reported:
• The ‘total fuel quantity at departure’ was read from the totaliser set to the ‘fuel
remaining’ mode after refuelling had been completed. The totaliser was
preferred to the fuel quantity indicators because it provided a digital presentation
that was easier to read than a gauge pointer.
- - 24
• Most pilots reported that they obtained the ‘burn’ fuel by calculating the
difference between the ‘total fuel quantity at departure’ and the ‘residual’ at the
end of a flight. Three pilots, including the fleet manager, stated that they
obtained ‘burn’ fuel from the totaliser set to the ‘fuel used’ mode.
• ‘Residual’ fuel was read from the totaliser set to the ‘fuel remaining’ mode after
the engines had been shutdown and before the totaliser had been updated.13 For
the first flight of the day, the ‘residual’ fuel was generally copied from the final
residual figure from the previous flight log.
• ‘Added’ fuel was obtained by converting the refuelling docket quantity in litres
to kilograms. The operator’s manuals prescribed that ‘0.8’ was to be used as the
specific gravity of aviation turbine fuel for the conversion.
The investigation team reviewed a sample of the operator’s flight logs (see 1.17.5).
This review revealed that, of the 22 different pilots in command who completed
aircraft flight logs, only three appeared to use the totaliser ‘fuel used’ function to
calculate fuel ‘burn’. Those pilots included the fleet manager, the pilot in command
of VH-XUE on the occurrence flight (who changed to the practice following 4
April 2007 after being advised to do so by the fleet manager) and another pilot in
command (who changed to the practice after 18 June 2007).
1.12.4 Refuelling to a known quantity
The operator’s pilots reported that, for operational reasons, they rarely refuelled the
EMB-120 aircraft to full capacity during normal operations. However, the review of
flight logs noted that there were four occasions when the occurrence aircraft may
have been refuelled to full capacity. On 6 November 2006, 19 December 2006 and
29 April 2007, the recorded totals prior to departure were close to the published
capacity of the fuel system (2,600 kg, assuming a specific gravity of 0.785). On 28
April 2007, the recorded total prior to departure was 2,700 kg and that exceeded the
manufacturer’s fuel capacity of 2,622 kg.
1.12.5 Discrepancies between recorded and actual fuel quantities
The flight logs for VH-XUE were reviewed to identify potential events or factors
that could explain the discrepancy between the recorded fuel quantity and the actual
fuel quantity that was evident on the occurrence flight. The flight logs for the
operator’s other five EMB-120 aircraft were also reviewed for the period 1 April
2007 to 25 June 2007 for comparison purposes.
The review of the flight logs also revealed that for each EMB-120 aircraft during
the period 1 April to 25 June, the total fuel added exceeded the total fuel used by
about 3% of the fuel added. That excess was due to two factors:
• The operator’s use of a specific gravity for Jet A1 fuel of 0.8 to convert fuel
litres to kilograms (a specific gravity of 0.785 was used predominantly through
13 It was reported that some pilots regularly reset the totaliser during flight. The reason for doing a
reset was to ensure that the fuel remaining display matched the fuel gauge display. It was reported
that, by the end of a flight, the difference between the two figures was often about 20 to 30 kg if
the totaliser was not reset.
- - 25
the industry and, immediately following the occurrence, the operator amended
its procedures to require that value to be used). The numerical difference
between the fuel added and fuel used would have been less if 0.785 had been
used.
• The ‘burn’ figures did not include APU fuel that was burned before the total fuel
at departure figure was calculated.
Until April 2007, the figures for VH-XUE were similar to the operator’s other
EMB-120 aircraft. However, between April 2007 and the occurrence date, the
exceedance for VH-XUE (about 0.3% of fuel added) was much less than for the
other aircraft. Most of that difference appeared to be due to VH-XUE having a
higher recorded fuel burn after about March 2007.
Overall, due to the practices for recording fuel information, it was not possible to
track with precision when erroneous fuel quantity indications began.
1.12.6 Cross-checks of total fuel quantity at departure
Consistent with the operator’s procedures, the operator’s pilots reported that the
‘total fuel quantity at departure’ was cross-checked against a figure calculated by
adding the ‘residual’ from the previous flight and the ‘added’ fuel. A discrepancy of
60 kg or more between the indicated total fuel and the calculated total fuel figures
required resolution to the satisfaction of the crew. If the discrepancy could not be
resolved, then dripless measuring sticks were used to confirm the quantity in the
tanks. The reason for any discrepancy of 60 kg or more was noted in the ‘comments
/ observations’ section of the flight log.
The pilots reported that the most common reason for a discrepancy between the
totaliser total fuel figure and the calculated total fuel figure was due to APU fuel
burn prior to obtaining the total fuel quantity at departure. APU fuel burn was not
normally recorded on the flight log. However, if APU fuel burn explained a
discrepancy of 60 kg or more between the totaliser total fuel figure and calculated
total fuel figure, then APU fuel burn would be noted in the ‘comments /
observations’ section.
The review of flight logs found that during the period 1 April to 25 June 2007, there
were 68 occasions across all six EMB-120 aircraft when the difference between the
recorded ‘total fuel quantity at departure’ figure was 60 kg or more different to the
applicable calculated figure. On 51 occasions, the reason provided was ‘APU burn’.
No reason was provided on 15 occasions. Seven of the 51 events involved VH-
XUE. Flight logs for VH-XUE during the period 15 October 2006 to 31 March
2007, indicated a similar pattern. In all but one instance where the difference was
60 kg or greater, the total fuel quantity at departure was less than the calculated
amount. The only exception involved VH-XUE, which occurred on 30 April 2007.
1.12.7 Residual fuel quantity variations between days
Pilots reported that prior to the first flight of the day, they compared the residual
figure recorded from the previous flying day with the quantity indicated by the
totaliser or fuel quantity indicating system. There was no procedure to follow in the
event of a discrepancy between the residual figure and the indicated figure. Some
pilots reported that they would wait to conduct a cross-check after fuel was added.
- - 26
If the total fuel quantity check was within limits, then no further action was
required.
Further examination showed that:
• During the period 1 April to 25 June 2007, there were 29 occasions involving all
six EMB-120 aircraft when the final residual fuel at the end of a day’s
operations was different to the residual figure on the flight log for the first flight
the following day.
• On nine occasions, the difference was 60 kg or more. No reasons were provided
on the flight log to explain those differences.
• On most of the occasions, the change in the residual figure brought the
calculated total fuel figure to within 60 kg of the totaliser total fuel figure for the
first flight of the following day.
• Flight logs for VH-XUE during the period 15 October 2006 to 31 March 2007
indicated a similar pattern to the other aircraft during the period 1 April to 25
June 2007.
1.12.8 Use of dripless measuring sticks
The operator’s pilots reported that dripless measuring sticks rarely had to be used to
resolve fuel quantity discrepancies. Several pilots reported that they had been
shown how to use dripless measuring sticks during line training, but had not needed
to use them in normal operations. It was also reported that, if they were used, this
would not always be documented on the flight logs.
The review of flight logs identified two instances that recorded the use of dripless
measuring sticks. Both involved the same pilot in command and were used to
confirm discrepancies in the totaliser total fuel figure and the calculated total fuel
figure following maintenance activities. Neither instance involved the occurrence
aircraft.
1.12.9 Recording of fuel used by maintenance personnel
There have been previous occurrences where use of fuel during maintenance
activities, such as engine ground runs, was not recorded (see ATSB Investigation
Report BO/20050476814). In contrast, the review of flight logs used by the operator
of VH-XUE revealed many instances where maintenance personnel had recorded
fuel used during maintenance activities.
1.12.10 Auditing of fuel use and recording practices
The operator’s Flight Standards Manual, Section 1.6.2, listed the responsibilities of
the flight operations manager. One of those was to ‘audit the safety, quality and cost
efficiency of all flight operations’.
Pilots reported that the flight logs were audited on a sample basis by a pilot
delegated by the fleet manager. Each flight log was checked for its accuracy, but
there was no analysis of recorded fuel quantity data beyond more than one flight
14 http://www.atsb.gov.au/publications/investigation_reports/2005/AAIR/aair200504768.aspx.
- - 27
log. Any problems identified on the flight logs were notified to the relevant pilots.
When problems were identified, they usually related to weight and balance or flight
hours rather than fuel figures.
1.13 Related fuel quantity occurrences
1.13.1 Previous EMB-120 occurrence in Australia (14 January 2005)
The ATSB aviation safety occurrence database included one previous event
involving fuel starvation in an EMB-120 aircraft on 14 January 2005. That event
was classified by the ATSB as a Level 515 occurrence. Consequently, there was no
ATSB investigation and only minimal information was obtained from the operator
regarding the occurrence. However, following the VH-XUE occurrence, the
operator involved in the 14 January 2005 occurrence provided further information
on the event to the ATSB.
That operator advised that, during the 14 January 2005 event, the right engine
ceased operating shortly after the crew observed a low fuel pressure caution. At the
time, the right fuel quantity indicator was fluctuating between 300 and 500 kg,
while the left was steady at 500 kg. After a single-engine approach and landing, the
right indicator read 250 kg, and the left 500 kg. Prior to departure, both the left and
right indicators showed 1,500 kg. A subsequent check revealed that the right tank
contained no fuel. A faulty number-6 fuel probe was found to have caused the
incorrect indication. The reason for the faulty probe was not determined.
Before the flight, the crew noticed a discrepancy between the gauge reading of
900 kg and the recorded fuel remaining figure of 400 kg from the previous flight.
However, because the aircraft had just returned from maintenance, they assumed
that fuel had been added by engineering staff, but had not been recorded. The
crew’s fuel quantity check, based on the residual fuel being 900 kg, fell within the
required 3% margin.
Immediately following the occurrence, the operator amended its procedures to
require that the dripless measuring sticks be used to confirm the fuel quantity before
the first flight of the day. A further direction prohibited an aircraft being dispatched
in the event of a discrepancy between the residual fuel recorded in the flight log and
the gauge indication.
1.13.2 Other EMB-120 fuel-related occurrences
On 22 February 2008, the aircraft manufacturer advised the ATSB that another in-
flight engine power loss due to fuel starvation involving an EMB-120 aircraft
occurred in Europe on 20 February 2008. Preliminary information indicated that,
shortly after commencing descent from flight level (FL) 190, the crew observed a
right engine fuel pressure low warning. They then noticed that the engine torque
15 Resource constraints limit the number of investigations that the ATSB can initiate and conduct
each year. As such, difficult decisions are often required in determining which occurrences are
investigated. Where a decision is made not to investigate, details of the occurrence are included in
the ATSB’s data base for trend monitoring and/or future reference (see www.atsb.gov.au).
- - 28
was zero. There was 400 kg fuel indicated by both fuel quantity indicators at the
time. The crew secured the engine and completed an uneventful landing at the
destination airport.
A check revealed that the right wing tank contained no fuel. Before the flight, the
crew had found a discrepancy between the refuelling panel quantity indicator and
the cockpit indicator for the right tank. The matter was reported to have been
rectified and agreement achieved between the refuelling panel and cockpit
indicators, and the right tank fuel quantity after shutdown on the previous flight.
There was no information as to whether a drip stick reading had been taken to
confirm the fuel quantity. The manufacturer was gathering further information on
the occurrence, including recorded flight data.
The aircraft manufacturer advised that it knew of four other instances of fuel
starvation in EMB-120 aircraft. They included:
• November 1993 - During landing phase, left engine auto shutdown. Continued
landing sequence without incident. Found left engine flamed out due to no fuel.
Fuel totaliser, both master fuel quantity indicators and both fuel repeaters,
showed indication to be correct. Replaced left fuel quantity indicator. Indication
checks normal against dripless stick. After fuelling the aircraft, all engine
parameters check normal. TAT, 12,106.6 Hours.’
• December 1993 - While enroute ... the right engine torque went to zero. Shut
engine down and feathered prop, and landed ... without incident. Maintenance
inspected system and found that the right fuel quantity gauge was reading
500 lbs high, and the right engine had run low on fuel. Maintenance removed
and replaced the right fuel quantity gauge, IAW the Embraer maintenance
manual Chap 28-41-00. System ops checked good. Aircraft approved for return
to service.’
• June1999 - The right fuel indicator was stuck in 510 lbs, and the right tank
become empty. This condition caused the flame out on the right engine. ... event
was solved by replacing the fuel quantity indicator.’
• 14 January 2005 - No details were available.
1.13.3 Other fuel-related occurrences
In addition to the 14 January 2005 occurrence and the 26 June 2006 occurrence
involving EMB-120 aircraft, there were three other occurrences investigated by the
ATSB involving power loss on an engine due to fuel starvation in commuter or
transport category aircraft. Each of those occurrences involved a technical failure of
the fuel quantity indicating systems and problems associated with the operators’
procedures for cross checking fuel quantity. Further details of those occurrences are
provided in Appendix B.
1.14 Communication of important safety information to the industry
It became apparent during the investigation that there was little formal or informal
communication between Australian EMB-120 operators aside from a conference
sponsored by the aircraft manufacturer that was held every 2 years. That conference
was usually attended by all the Australian operators and included a ‘closed-door’
- - 29
operators-only session, which provided the opportunity for the exchange of
information. It was at such a session in November 2005 where details regarding the
14 January 2005 occurrence were discussed, but the operator of VH-XUE was
unable to attend that session of the conference. As a result of learning of the
14 January 2005 occurrence, the other Australian EMB-120 operators at the
conference amended their procedures to require daily drip stick measurements of
fuel quantity.
The aircraft manufacturer advised that it had not been notified of the 14 January
2005 occurrence. The manufacturer had in place a system for issuing Operator
Advisory notices concerning safety and other information regarding an aircraft type
to all operators of that type, and indicated that events such as that of 14 January
2005 would result in the issuing of an Operator Advisory.
While the ATSB obtained only descriptive event data about the 14 January 2005
occurrence, a CASA inspector conducted an examination of the occurrence.
However, CASA did not advise other Australian EMB-120 operators or the
manufacturer of the circumstances of the occurrence, or of the revised fuel quantity
measurement procedures that had been introduced as a result.
1.15 Operational procedures
1.15.1 Crew resource management
Section 2.4 of the operator’s Flight Standards Manual, stated that the Crew
Resource Management (CRM) theory course was to be completed by all new crew
members as soon as practicable and that all crew members would receive refresher
training in the subject at least every 2 years.
Section 3 of the operator’s Flight Operations Manual was titled Crew Resource
Management. It included information on threat and error management, decision
making, and the support process between crew members.
Section 3.8 of the Flight Operations Manual addressed ‘crew coordination’ and
specified the responsibilities of the pilot flying and the monitoring pilot as follows:
3.8.5 Pilot Flying [PF]
The Pilot Flying [PF] shall primarily be responsible for flying the aircraft and
maintaining a good lookout when in visual conditions
In circumstances where the Monitoring Pilot [MP] is preoccupied with a task
or under a high workload, the Flying Pilot may assist with other tasks
provided the action does not deter from the primary task of flying the aircraft.
During abnormal and emergencies, the Pilot Flying shall confirm checklist
actions.
3.8.6 Monitoring Pilot [MP]
The monitoring pilot's primary duty is to provide support to the flying pilot.
The duties shall include:
Provide assistance in maintaining a good lookout in visual conditions;
Make radio calls and passenger PA’s;
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Action the airborne sections of the normal checklists;
Action cockpit paperwork including trip records, trend records, navigation
logs, load sheets and TOLD [takeoff and landing data] cards;
Tune and identify radio navigation aids as directed by the PF;
Action GPS operational needs;
Manipulate weather radar; and
Action specific tasks at the request of the PF.
When descending in cloud, monitor for visual reference and call when
established visual.
Identify aircraft malfunctions during abnormals and emergencies.
Read and action (if physically possible) checklist items during abnormals and
emergencies.
1.15.2 Procedures for go-around
The operator’s Brasilia Flight Operations Manual, Section 2, Normal procedures,
defined the procedures for a go-around from final approach with both engines
operating. Section 2, Abnormal and Emergency Procedures, paragraph 3.3.4
defined the procedures for a single engine go-around/missed approach. The initial
actions were identical for both procedures and were as follows:
FLYING PILOT MONITORING PILOT
Call, “GOING AROUND, SET POWER,
FLAP 15”
Press the Flight Director Go-Around button and pitch up to follow the command bar. At the same time Advance Power Levers to within 10% of the pre-determined target torque When a positive rate of climb is established call, “GEAR UP”
Set the pre-determined target torque, select Flaps to 15 and call, “POWER SET”. and call “FLAPS
15” when 15 flap is indicated Select Gear Up and when fully retracted call “GEAR UP”
Those procedures reflected the aircraft manufacturer’s recommended procedures.
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1.15.3 Procedures for operations on unpaved surfaces
Aircraft manufacturer
The aircraft manufacturer published procedures for operations on unpaved surfaces
in Supplement 14 to the EMB120 Brasilia Airplane Flight Manual. The supplement
stated that:
Non-normal landing can be made with either flap 25 or flap 45, as applicable,
and
Normal landing must be made with flaps 45.
Aircraft operator
The operator’s Brasilia Flight Operations Manual, Section 2, Normal Procedures,
paragraph 2.11.3, included the following information regarding flap selection:
Flap 25 shall be the landing flap selection for all instrument approaches unless
the runway length or surface requires Flap 45.
Paragraph 1.9.2, Unpaved Runway Operational Requirements, in Section 1 of the
operations manual stated that flap 45 must be used for landings on unpaved
surfaces, but that flap 25 or 45 could be used as required in the case of a non-
normal landing on an unpaved surface.
Flap selection
The operator’s Brasilia Flight Operations Manual, Section 2, paragraph 2.11.3,
Flap Selection, was as follows:
For runway approaches to aerodromes requiring Flap 45, the selection of Flap
45 shall not be made until the aircraft has been established visual. For circling
approaches to aerodromes requiring Flap 45, the selection of Flap 45 shall not
be made until the aircraft is positioned on final approach to the runway. In
both cases, aircraft must be stabilised in the final approach configuration by
300’ AGL.
The operator advised that the majority of landings conducted away from the
operator’s home base were to unpaved runways, and therefore required flap 45 in
accordance with the manufacturer’s procedures. Landings on sealed runways were
almost always done in the flap 25 configuration.
The operator reported that pilots were made aware during training that once flap 45
had been selected, or when the aircraft reached 300 ft above runway elevation, the
approach should be continued to landing in the event of an engine failure. Training
had also included the requirement to use no more than flap 25 for single-engine
approaches.
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1.16 Flight crew endorsement and line training requirements
1.16.1 Regulatory requirements
Civil Aviation Order (CAO) 40.1.0 prescribed the requirements for aircraft
endorsements. CAO 40.1.4.4 stated that, to fly as pilot in command or copilot, the
holder of a class endorsement for the aeroplane must:
• be familiar with the systems, the normal and emergency flight manoeuvres and
aircraft performance, the flight planning procedures, the weight and balance
requirements and the practical application of take-off and landing charts of the
aircraft to be flown’;
• have sufficient recent experience or training in the aeroplane type, or in a
comparable type, to safely complete the proposed flight; and
• hold a specific endorsement for any ‘special design feature’ of the aircraft.
For aircraft with a maximum take-off weight of more than 5,700 kg, CAO 41.1.0
detailed separate syllabus requirements and conditions for acting as pilot in
command and copilot. For pilot in command, these were:
• flying training was to include at least 5 hours flying time in conformity with
specified criteria involving general handling, takeoff, instrument flying,
asymmetric flight, and night flying, plus
• at least 50 hours flight time as pilot in command under supervision; or
• 25 hours flight time as pilot in command under supervision, and the successful
completion of an approved training course in an approved synthetic trainer.
In the case of a copilot, the syllabus was to include at least 3 hours flying time,
which was to cover takeoff, medium and steep turns, asymmetric flight, night flying
and general handling.
For aircraft with a maximum take-off weight of 5,700 kg or less16, the CAO did not
include any requirements regarding the number of flying hours the endorsement
training for that weight class of aeroplane was to include.
1.16.2 Operator’s requirements
At the time of the occurrence, Section 2.7 of the aircraft operator’s Flight Standards
Manual included the following information regarding endorsement training:
Although the following table specifies the minimum aircraft experience
required for aircraft endorsement, the flight time necessary to meet the
required proficiency standard may be more than the minimum.
16 For example, the Beech King Air 200 has a maximum take-off weight of less than 5,700 kg. The
King Air 200 is a high performance, sophisticated turboprop aircraft that is used for fare-paying
passenger, aerial work and private corporate operations. There were 38 King Air 200 aircraft on
the Australian register at the time of publication of this report.
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Aircraft type Minimum endorsement
hours
Turbo-prop < 5700 kg 5
Turbo-prop > 5700 kg command 5
Turbo-prop >5700 kg 3
The hours required for an endorsement to be conducted in the simulator are
detailed in the type specific training manual.[17]
The syllabus for flight training for the relevant aircraft endorsement is
contained in the applicable type specific training manual.
Aircraft endorsement training is currently conducted in the aircraft with the
exception of the Dash 8 and Metro aircraft whereby the endorsement training
may be conducted in the appropriate Flight Simulator.
Section 2.10.3 of the Flight Standards Manual stated that:
…at the completion of a check to line, the candidate must have completed at
least:
- In the case of EMB-120 pilot in command, 50 hours in command
under instruction, and
- In the case of EMB-120 copilot, 30 hours line training.
Of relevance to the occurrence, the syllabus for EMB-120 flight training included,
in Sortie # 4, a simulated emergency procedure followed by engine shutdown and
restart above 8,000 ft, a simulated single-engine circuit procedure and go-around
with flaps 25 set, and a single-engine approach and landing. Sortie #5 included a
circuit and landing, and a go-around, in simulated asymmetric conditions. Sortie # 6
included a simulated asymmetric instrument approach and overshoot. At the time,
those elements were similar to the syllabus content for other Australian operators of
the EMB-120.
1.16.3 Other EMB-120 operators training requirements
A US-based operator of a large fleet of EMB-120 aircraft advised that:
• for passenger-carrying operations, it used a system where 80% of check flights
were completed in an EMB-120 simulator and 20% in the aircraft
• the simulator was used for all endorsement and recurrent training
• EMB-120 endorsement training involved 20 hours simulator training and
2 hours aircraft training
• upgrade training from copilot to PIC involved 20 hours simulator training and
2 hours aircraft training
• up to 50 hours line training was undertaken following endorsement training.
17 The operator’s Brasilia Training Manual did not contain any information regarding EMB-120
simulator training.
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The aircraft manufacturer advised that its initial and recurrent EMB-120 training
system was approved by the national regulator. Initial (endorsement) training
involved 20 hours minimum and annual recurrent training involved a minimum of
8 hours, plus a check flight. The training could be completed on the aircraft or in a
simulator, but was usually done in the simulator for cost and safety reasons.
1.17 Flight simulators
1.17.1 Background
The importance of flight simulators as efficient and effective tools in flight crew
training is widely recognised and accepted. Flight crew training in some emergency
procedures, including major systems failures during critical flight phases, is
generally not able to be practised in an aircraft because of safety considerations.
Simulators are not similarly constrained or limited.
In the case of an EMB-120 flight simulator, for example, there were about
225 separate malfunctions that could be practised to the extent where the crew
operated switches and controls, and observed and experienced the outcomes, as
they would in the real situation. In contrast, only about 13 emergency
procedures and system malfunctions could be safely demonstrated and practiced in
the actual aircraft. Training for other malfunctions that could not be safely
demonstrated and practiced in the aircraft, was subject to limitations such as height
restrictions, touching as opposed to operating controls and switches, or classroom
discussion, which substantially reduced training effectiveness in those areas.
Large airlines generally are able to afford to purchase and operate simulators for
training their own crews. Without the benefits of economies of scale afforded to
large airlines, operators of smaller fleets were generally unable to afford their own
simulators. That was the situation for Australian EMB-120 operators in the period
leading up to the occurrence. The only means by which they could conduct
simulator training was to send crews to a facility outside Australia. At the time of
the occurrence, there were EMB-120 simulators in North America, South America,
and Europe. The costs, both in dollar terms, and in terms of time away, of sending
crews for simulator training at those locations, were significant.
1.17.2 Australian regulatory requirements
At no time before the occurrence had the operator of VH-XUE used flight
simulators as part of its EMB-120 flight crew training. There was no Australian
regulatory requirement for simulators to be used for flight crew training and there
was no EMB-120 flight simulator facility in Australia.
Civil Aviation Order (CAO) 40.1.0 (as amended) stated that ‘the person seeking the
endorsement must … undertake flying training, or training in an approved synthetic
flight trainer appropriate to the type of aeroplane, in normal and emergency flight
manoeuvres and procedures in that type of aeroplane’
CAO 40.2.1 (Instrument ratings) stated:
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A synthetic flight trainer may be approved for the purpose for accruing
instrument time as required by paragraph 8.3 of this section, and to meet
specified flight test and recent experience requirements.
There was provision in the Orders for simulator training to be conducted at
locations outside Australia, provided those simulators had appropriate approvals.
1.17.3 Overseas regulatory requirements
USA
The US Federal Aviation Administration (FAA) Regulations Part 121.409 –
Operating Requirements: Domestic, Flag, and Supplemental Operations, Subpart N
–Training Program, was titled Training courses using airplane simulators and other
training devices. It listed the conditions under which flight simulators may be used
as part of an approved training program. Those requirements included that the:
• training must include at least 4 hours at the controls for each trainee
• program includes at least the manoeuvres and procedures (abnormal and
emergency) that may be expected in line operations
• program must include line oriented flight training that involved a complete crew
• approved simulator must provide training in low-altitude windshear avoidance.
Europe
The European Aviation Safety Agency NPA No 2008-17B – draft decision on
acceptable means of compliance and guidance material on the licensing and
medical certification of pilots, included the following guidance in regard to flight
simulators:
• A simulator shall be used for simulated asymmetric flight, if one is available.
• Simulated engine failure during takeoff must be conducted at a safe altitude
unless carried out in a flight simulator.
• A flight simulator shall be used for practical training and testing if the simulator
forms part of an approved type-rating course.
• Training in engine failures between V1 and V2, in windshear at takeoff and
landing, in collision avoidance system operation, and in ‘tuck under and Mach
buffets after reaching the critical Mach number, and other specific flight
characteristics of the aeroplane (e.g. Dutch Roll)’, shall only be conducted in a
simulator.
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Canada
Canadian Aviation Regulation S744.115(8) included the following conditions
affecting the use of flight simulators:
Synthetic training devices should be used for training at every opportunity.
The term synthetic training device refers to full flight simulators and flight
training devices.
Canadian air operators may use a foreign simulator for the purpose of
training, licensing or checking flight crews, provided those simulators have
TCA [Transport Canada] approval.
For turbo-jet aircraft, the required training may be conducted on the aeroplane
only if a synthetic flight training device is not available in North America. For
pressurized turbo-prop aircraft, Transport Canada encourages carriers to
conduct training on the simulator, or to use a combination of training in an
FTD [flight training device] and the aeroplane.
New Zealand
The New Zealand Civil Aviation Rules, Part 121.579 Manoeuvres requiring a flight
simulator, stated:
Each holder of an air operator certificate shall ensure a flight simulator is used
where a non-normal or emergency manoeuvre is to be conducted during
training, practice, or a competency check that—
(1) if mishandled, would create an unacceptable risk to the aeroplane, crew
members, or third parties; or
(2) is carried out in close proximity to the ground or water; or
(3) involves the need to fail any system for training that cannot be readily
failed in the aeroplane without an unacceptable risk to the aeroplane, crew
members, or third parties; or
(4) involves actions necessary to complete any procedures required by
121.77(d) (4) that cannot be realistically carried out in an aeroplane.
1.17.4 Use of simulators by Australian regional operators of turboprop aircraft with 19 seat or greater capacity
At the time of the publication of this report, there were 18 Australian operators of
turboprop aircraft of 19 seats or greater capacity. The fleets of some of those
operators comprised several of one aircraft type and other fleets comprised one or
two of a specific aircraft type. Some fleets comprised two or three different types in
a fleet size of less than 10 aircraft. As part of the investigation, a sample batch of 12
operators was surveyed regarding simulator training (because the larger single-type
regional airline fleets were mature users of simulators, they were not included in the
survey).
Information gained during the survey included the following:
• All operators were in favour of using simulators for initial and recurrent
training, recognising the ability to undertake training in all aircraft emergency
situations, along with training two-pilot operations, as the prime advantages of
simulator training.
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• Where there was the relevant simulator type in Australia, most operators utilised
the simulator for endorsement training, while some also performed recurrent
training in the simulator.
• Operators who did not utilise Australian-based simulators cited travel costs and
time away as the reasons. Their preference, however, was to use simulators for
endorsement and recurrent training. Those operators were located in northern
and western Australia.
• In a few cases, an operator’s fleet included only one or two 19-seat turboprop
aircraft for which there was no simulator in Australia. Those operators reported
that the costs involved in sending pilots to overseas simulator facilities were
considered prohibitive, although they preferred simulator training.
• All operators who utilised simulator training reported that CRM training was an
integral component of endorsement and, where applicable, recurrent training.
• CRM training for operators who did not utilise simulator training generally
involved a 1-day course once per year.
• All operators thought that mandating the use of simulators for flight crew
training in 19-seat turboprop aircraft was a good idea. Some operators thought
that cost would be an issue in some cases and suggested some form of
subsidisation would help ‘level the playing field’.
• Operators not using simulators reported that they conducted emergency training
in the aircraft to the extent that it could be safely undertaken. Training for other
emergencies was covered ‘by discussion’.
• Endorsement training in a simulator usually involved 20 to 32 hours ‘flight’
time, with half that time as flying pilot and the other half as monitoring pilot but
functioning as part of the crew. That compared with endorsement training that
was conducted solely on the aircraft, which typically involved between 5 and
7 hours flight time with a check and training pilot.
• The majority of the operators surveyed believed that generic, fixed-base flight
simulators had the potential to provide significant training benefits. Some
operators had their own generic simulators, which they used for training in
emergency procedures and some aspects of instrument flying. However, such
training had not been approved by CASA as a substitute for training in an
aircraft or a type-specific full flight simulator. CASA had not discouraged the
use of generic simulators, but required the operator to demonstrate the benefit
before credits could be awarded for generic simulator use.
• Some operators had received bonuses from clients because they had moved to
conduct training on simulators. In general, however, the use of simulators did
not bring any significant advantage from external agencies such as insurance
companies or clients.
1.17.5 Transport category turboprop aircraft simulators in Australia
There were organisations in Australia and internationally that operated one or more
simulators and provided training to outside parties on a commercial basis. One such
organisation in Australia operated simulators for the SAAB 340A/B, Metro III,
Dash 8-Q100/Q200/Q300 and Beech 200 turboprop aircraft. That same organisation
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acquired an EMB-120 flight simulator in mid-2008 and that facility became
operational in April 2009.
The organisation reported that it had undertaken an analysis of the real cost of
aircraft training compared to full flight simulator training. The results indicated that
even when taking into account airfares, accommodation and allowances for aircrew,
simulator training was the cheaper option. The organisation reported that aircraft
operators generally look only at initial operating costs such as fuel to determine the
viability of aircraft training verses simulator training. That was not a true
determination when all aircraft operating costs, including: maintenance, insurance,
depreciation, air navigation charges and aircraft rescheduling and crew costs were
taken into consideration.
1.18 Recent serious occurrences involving transport category turboprop aircraft in Australia where aircraft handling was a factor
Since 1995, there have been five serious occurrences involving transport category
turboprop aircraft in Australia where aircraft handling was a factor. Aside from the
subject occurrence, the others were:
• Fairchild Industries Inc SA227-AC, VH-NEJ, Tamworth, NSW 16 September
1995. Two trainee pilots were killed, and the endorsing pilot seriously injured
after the aircraft was mishandled during a simulated engine failure on takeoff at
night.
• Beech 1900D Airliner, VH-NTL, Williamtown, NSW 13 February 2000. During
a training flight, the crew lost control of the aircraft on two occasions while
conducting engine failure training exercises.
• Beech Aircraft Corporation King Air C90, VH-LQH, Toowoomba, Qld 27
November 2001. The pilot and three passengers were killed when control of the
aircraft was lost following an engine failure as the aircraft became airborne.
• Fairchild Industries SA227-AC Metro III, VH-TAG, 33km ENE Canberra, ACT
21 November 2004. The crew lost control of the aircraft twice while conducting
engine failure training exercises.
Summaries of those occurrences are included at Appendix D.
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2 ANALYSIS
2.1 Overview
In this serious incident, the left engine lost power following fuel starvation due to
lack of fuel in the left tank, which occurred at a critical stage of the flight when the
aircraft was in a high drag configuration, at low speed, and close to the ground.
Central to the development of the incident was the fact that the crew did not detect
the engine power loss. Consequently, when the aircraft became misaligned with the
runway, they initiated a go-around in the expectation of a normal aircraft response.
The crew was surprised by the significant roll and yaw, consequences of
asymmetric thrust, and did not complete the standard go-around initial actions of
setting engine power and selecting flaps 15, and retracting the landing gear. Those
omissions severely limited the performance of the aircraft and the amount of
aircraft control available to the crew. Flaps 25 was selected 24 seconds after the go-
around was initiated. During that time, the aircraft turned left through about 45° ,
rolled to 34° left bank, the speed decreased from 110 to 96 kts, and the aircraft
descended to about 250 ft above ground level (AGL). After the flaps reached 25°,
aircraft performance deteriorated further with the speed in the range 95 to 97 kts for
12 seconds, and the altitude decreasing to about 50 ft AGL. The flaps were fully
retracted and the landing gear retracted 3 minutes 6 seconds after the go-around was
commenced. The left engine shut-off was selected 4 minutes 20 seconds after the
go-around was commenced.
The stick shaker operated twice during the go-around, but because stick shaker
operation was not a flight recorder parameter, the timings of those events could not
be established. The recorded flight data indicated that the aircraft remained on the
limit of its performance limits for about 1 minute 21 seconds after the go-around
was initiated. The avoidance of a ground collision during that period was fortuitous.
The investigation identified safety factors associated with the fuel quantity
indicating system, the ability of the crew to recognise the left engine power loss,
and their performance during the go-around. There were clear indications that the
fuel quantity measurement procedures and practices employed by the operator were
not sufficiently robust to ensure that a quantity indication error was detected. The
failure of that risk control provided the opportunity for other safety barriers
involving both the recognition of, and the crew’s response to, the power loss, to be
tested. Organisational safety factors involving regulatory guidance, the operator’s
procedures, and flight crew practices were also identified in those two areas.
2.2 Fuel quantity indicating system faults
The comparison between the fuel tank contents and the fuel quantity indicator
readings after the occurrence, confirmed that the left indicator was over-reading.
The nature of the damage to the left tank number-6 fuel probe was consistent with
the over-reading being as a result of short circuit activity in the damaged section of
the wiring loom. The condition of the wiring indicated that it was likely to have
been gradually deteriorating over time and due, in part, to slight rubbing of the
wires against one another during normal aircraft operations. The nature and location
of the damage meant that it was unlikely to have been evident during normal
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maintenance activities. The consequence of the probe and loom damage was to alter
system capacitance and feed erroneous signals to the fuel quantity indicator,
irrespective of whether the probe was, or was not, immersed in fuel. Regardless of
the nature of the fuel quantity indication system malfunction, if the crew had taken
a drip stick reading before the flight, it is very likely that the left fuel quantity
indicator error would have been discovered.
Analysis during the investigation of flight logs did not reveal when the fuel quantity
indicator began to over-read. However, the practices of not accurately recording
auxiliary power unit (APU) burn fuel quantities and of using a specific gravity
value of 0.8, limited the effectiveness of the analysis. Nevertheless, it was apparent
that the recorded fuel quantity data for the Empresa Brasileira de Aeronáutica S.A.
EMB-120ER aircraft, registered VH-XUE, in March 2007, demonstrated
characteristics that were different from the remainder of the operator’s fleet, and
which were not evident previously. On that basis, it is possible that errors in the fuel
quantity indicating system of VH-XUE were present for some time before the fuel
starvation event at Jundee.
The only prospect of the flight crew detecting the erroneous fuel quantity indication
before the flight was to check the fuel quantity by a method that was completely
independent of the capacitance fuel quantity indicating system. The only means of
achieving that in the EMB-120 aircraft was by using the dripless measuring sticks.
2.3 Fuel quantity measurement
Safety factors involving fuel quantity measurement encompassed regulatory
guidance on fuel quantity checks and the operator’s procedures and practices for
measuring fuel quantity.
2.3.1 Regulatory guidance
In broad terms, the guidance contained in the Civil Aviation Safety Authority’s
(CASA’s) Civil Aviation Advisory Publication (CAAP) 234-1(1) (as revised in
November 2006), and previously included in Civil Aviation Orders (CAOs),
allowed two options for establishing fuel on board:
• full tanks, or ‘a totally reliable and accurately graduated dipstick, sight gauge,
drip gauge or tank tab reading’; or
• a cross-check by at least two different methods.
The CAAP did not clearly indicate whether, or why, one option had advantages, or
was preferred, over the other. For example, the use of the phrase ‘totally reliable’
could be interpreted as meaning that the methods associated with that phrase were
the only ‘totally reliable’ methods. The CAAP, in effect, allowed operators to
choose the method that suited, or perhaps was most convenient, to them.
Two of the acceptable fuel quantity cross-check methods contained in the CAAP,
involved comparing the change in electrical gauge readings with a quantity
determined independently, either from a fuel consumed indicator, or from a
refuelling installation. However, neither of those methods would ensure detection of
a quantity indication error in cases where a gauge was under or over-reading by a
constant amount, or when there was a gradually increasing error. Only in cases
where fuel was added to an empty tank, or the aircraft tanks were filled to
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maximum capacity, would that method reveal a gauge error (See also Section 4,
Safety Actions).
The CAAP did not explain with sufficient emphasis that the purpose of the fuel
quantity check was to confirm the integrity of the fuel quantity indicator, and that a
‘totally reliable method’ provided the highest level of assurance in that regard. The
guidance, therefore, lacked clarity and direction and most likely influenced the
method chosen by operators to establish fuel quantity.
2.3.2 Operators procedures and practices for fuel quantity check
The fuel cross-check procedures that were published in the operator’s Brasilia
Flight Operations Manual, were a direct copy of the CAAP guidance. The
operator’s procedures were, therefore, consistent with the CAAP in that regard (as
were the procedures of a number of other operators - See Section 1.18). The
practice of checking fuel quantity by comparing added fuel with the difference in
gauge readings before and after refuelling had, for the most part, become embedded
within the pilot group. The complete absence (apart from two instances involving
the same pilot) of recorded use of the dripless measuring sticks demonstrated a lack
of understanding of the purpose of the check. It also implied a level of confidence
and trust in the fidelity of the fuel quantity verification method in common use. In
other words, there were signs that a culture existed within the flight crew group of
undue reliance being placed on the accuracy and reliability of the fuel quantity
indicating system.
The discrepancies in fuel quantity that had been recorded in the flight logs had been
attributed in many instances to ‘APU burn’. In some cases, noteworthy differences
between the indicated fuel quantity before refuelling and the recorded residual fuel
from the previous day were ignored. It is possible that, for some pilots, ‘APU burn’
became a convenient means of accounting for discrepancies. The practice of some
pilots of ignoring a disparity between fuel quantity indication and the recorded
residual fuel from the previous day until after refuelling had been completed may,
at least in part, have been because there was no procedure to cover that situation.
However, it might also have been because, in a general sense, discrepancies when
cross checking fuel quantity appeared to have become accepted as the norm
amongst crews, rather than the exception.
The evidence regarding the use of the fuel quantity totaliser indicated that there
were differences across the pilot group in the way that the fuel totaliser was used.
There appeared to be an incomplete understanding of the operation of the fuel
totaliser amongst some of the pilots that it was a system of measurement of fuel
used that was independent of the fuel quantity indicating system.
In summary, the operator’s procedures and practices that were intended to control
the risks associated with fuel quantity indicating systems, were ineffective.
2.3.3 Auditing of flight log fuel records
The operator’s auditing of fuel logs provided an opportunity for detecting errors in
fuel calculations, and for checking that crews were correctly following procedures.
At a higher level, it provided the opportunity for long-term statistical analysis of
fuel usage of individual aircraft as well as the entire fleet. The company’s audit
- - 42
process was not effective in any of those areas. It did not detect several instances
where differences of greater than 60 kg were noted in cross checks and there was no
apparent action taken to resolve those discrepancies by the flight crew. There was
also no process for analysing fuel usage trends. Long-term statistical analysis of
fuel usage across the operator’s fleet of EMB-120 aircraft would have highlighted
the issues that were apparent from the review undertaken as part of the investigation
(as detailed at paragraph 1.16.2). In turn, that might have lead to a deeper
examination of the fuel quantity indicating system in VH-XUE.
2.3.4 Fuel low level warning system
It is likely that the occurrence could have been avoided if the aircraft had been
equipped with a fuel low level warning system that was independent of the fuel
quantity indicating system. However, the certification standards against which the
aircraft was designed did not require the fitment of such a system. In the past few
years, following a series of fuel quantity-related occurrences, European
investigation agencies have issued safety recommendations for certification
standards to be enhanced to require independent fuel low level warning systems in
turboprop and turbojet aircraft (see Appendix B).
2.4 Flight crew performance
The absence of cockpit voice recorder data of the occurrence, limited the extent to
which the crew’s performance and interaction could be examined. Further, and as
might be expected after such an experience, the crew’s recollection of the event was
incomplete in some areas. However, there was sufficient evidence available to
enable some conclusions to be drawn.
There were a number of facets involving the crew’s performance that could be
classified as safety factors:
• The crew did not detect the loss of fuel flow to the engine, or the engine power
loss. Sun glare was a possible mitigating factor in terms of the crew noticing that
various warning and caution lights below the glareshield on the instrument panel
had illuminated. However, it was not clear why the crew did not hear the
accompanying warning chimes that, as far as could be determined, were
functioning at the time of the occurrence.18 Significantly, those events occurred
in circumstances where the crew were engaged in flying a high workload
segment of the flight and had no reason to suspect that there was not adequate
fuel on board the aircraft. Further, neither crew member had been exposed to an
engine power loss situation on late final approach, either in training or line
operations. The situation was, therefore, novel and unique for the crew. If the
crew had been exposed to engine power loss on final approach situations in a
flight simulator, it is likely that their diagnosis of the situation would have been
more timely and effective
• The crew did not keep the aircraft aligned with the runway during the approach.
It is likely that more positive input of the flight controls would have allowed the
aircraft to be kept aligned with the runway. However, the pilot flying was likely
18 There have been several previous occurrences where crews in high workload situations have not
heard cockpit alarms.
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to have manipulated the controls in the manner and to the extent that he had
become accustomed to during normal operations. In the asymmetric situation
that arose, in what was at the time a novel situation, such a technique was
unlikely to have been successful. The experience reported by the pilots who
attempted to replicate the occurrence in a flight simulator (See Section1.16.1)
provided an indication of the effort and difficulty the crew of VH-XUE would
have had in maintaining runway alignment.
• The crew did not execute the go-around procedure. The behaviour of the aircraft
after power was increased to go around was abnormal and, from the crew’s
perspective, without warning. The roll and pitch attitude changes reflected in the
flight data occurred despite the opposite rudder and aileron inputs initially
applied by the pilot flying. Although the crew performed some tasks in a
coordinated manner, they were unable to devote proper attention to the correct
procedure. It is likely that the unexpected behaviour of the aircraft alarmed and
focused the crew to the extent that they were unable to function effectively as a
crew.
• There was a delay in the crew’s diagnosis of the situation. The crew’s
recollection of two stick shaker activations, the enhanced ground proximity
warning system (EGPWS) warnings, and the recorded flight data, confirmed
that the aircraft was at, or near the limits of its performance envelope until after
the flaps reached the 25° position; some 35 seconds after the go-around was
initiated. Subsequently, more than 3 minutes elapsed before the left propeller
was feathered. The absence of cockpit voice recording information prevented
the proper examination of the crew’s activities during that period. Nevertheless,
the delay in executing the go-around procedures provided clear evidence that the
crew’s actions were uncoordinated during the go-around.
The quality of the crew’s performance depended largely on their ability to recognise
the engine power loss, and to respond to the situation by functioning effectively as a
team. There was strong evidence that the training they had received did not
adequately prepare them in either of those areas.
The training the crew had completed, while meeting regulatory requirements, was
not best practice for a complex, twin-engine turboprop aircraft such as the EMB-
120. For important safety reasons, training in many sequences involving critical in-
flight emergency situations can only be conducted in a flight simulator. Without the
benefit of simulator training, the crew was not adequately equipped to effectively
respond to an engine power loss on final approach in the flaps 45 configuration. A
similar argument would likely apply to many other possible emergency situations in
the aircraft. In that regard, the operator of VH-XUE was probably no different to
many other Australian operators of turboprop aircraft when flight crew training is
conducted without access to a flight simulator.
2.5 System for communicating important occurrence information to operators
The information regarding the January 2005 fuel starvation event involving an
EMB-120 aircraft from another operator was known by a number of parties, but not
the operator of VH-XUE. Receipt of that information by the operator of VH-XUE
would have provided an opportunity for the occurrence to be avoided.
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3 FINDINGS
From the evidence available, the following findings are made with respect to the
engine power loss and near loss of control involving Empresa Brasileira de
Aeronáutica S.A., EMB-120ER, registered VH-XUE, at Jundee, WA, on 26 June
2007 and should not be read as apportioning blame or liability to any particular
organisation or individual.
3.1 Contributing safety factors
• Regulatory guidance regarding the measurement of fuel quantity before flight
lacked clarity and appropriate emphasis and did not ensure that the fuel quantity
measurement procedures used by operators included two totally independent
methods. [Safety issue]
• The practices used by the operator’s pilots for measuring and logging of fuel
quantity were inconsistent. [Safety issue]
• Faults within the fuel quantity indicating system caused the left fuel quantity
indicator to over-read.
• The left engine lost power when the fuel in the left tank was exhausted.
• The flight crew did not detect the engine power loss.
• The aircraft became misaligned with the runway.
• The flight crew did not complete the go-around procedure actions.
• There was a significant delay before the crew configured the aircraft
appropriately for one-engine inoperative flight.
• The absence of simulator training meant that the endorsement and other training
the flight crew had undergone did not adequately prepare them for the event.
[Safety issue]
• There was no regulatory requirement for simulator training in Australia. [Safety
issue]
• The minimum requirements for endorsement training where simulator training
was not involved did not ensure pilots were aware of indicators and/or aircraft
behaviour during critical emergency situations. [Safety issue]
• The aircraft operator was not aware of important safety-related information
regarding the EMB-120 fuel system. [Safety issue]
3.2 Other safety factors
• There was no EMB-120 flight simulator training facility in Australia.
• The aircraft was not equipped with a fuel low level warning system.
• The certification standard to which the aircraft was built did not require the
aircraft to be equipped with a fuel low level warning system. [Safety issue]
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4 SAFETY ACTIONS
The safety issues identified during this investigation are listed in the Findings and
Safety Actions sections of this report. The Australian Transport Safety Bureau
(ATSB) expects that all safety issues identified by the investigation should be
addressed by the relevant organisation(s). In addressing those issues, the ATSB
prefers to encourage relevant organisation(s) to proactively initiate safety action,
rather than to issue formal safety recommendations or safety advisory notices.
All of the responsible organisations for the safety issues identified during this
investigation were given a draft report and invited to provide submissions. As part
of that process, each organisation was asked to communicate what safety actions, if
any, they had carried out or were planning to carry out in relation to each safety
issue relevant to their organisation.
4.1 Aircraft operator
4.1.1 Fuel measuring procedures
Safety issue
The practices used by the operator’s pilots for measuring and logging of fuel
quantity were inconsistent.
Action taken by the operator
On 1 July 2007, the operator amended its fuel quantity management procedures to
require:
• a dripless stick reading to be carried out each day, and for the results to be
recorded on the flight log
• auxiliary power unit (APU) fuel burn to be recorded on the flight log
• the aircraft to be placed unserviceable, and engineering assistance requested, if
dripless stick readings differed from the fuel gauge readings by more than 3%
• all flight logs to be checked on a daily basis
• the conversion factor for Jet A1 fuel to be changed from 0.8 kg/L to 0.785 kg/L.
ATSB assessment of response/action
The action taken by the operator appears to adequately address the safety issue.
4.1.2 Pilots inadequately prepared for event
Safety issue
The absence of simulator training meant that the endorsement and other training the
flight crew had undergone did not adequately prepare them for the event.
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Action taken by operator
In April 2009, following the certification of an Empresa Brasileira de Aeronáutica
S.A., EMB-120 flight simulator in Melbourne, Vic., the operator began utilising the
simulator for its EMB-120 flight crew training.
ATSB assessment of response/action
The action taken by the operator appears to adequately address the safety issue.
4.2 Civil Aviation Safety Authority
4.2.1 Fuel measuring procedures
Safety issue
The practices used by the operator’s pilots for measuring and logging of fuel
quantity were inconsistent.
Action taken by the Civil Aviation Safety Authority
On 3 July 2007, the Civil Aviation Safety Authority (CASA) issued a series of
directions to the operator which addressed fuel quantity measurement procedures
and flight crew training.
On 26 September 2008, CASA provided the following details regarding the actions
it had taken in response to the occurrence involving VH-XUE:
A summary of CASA activities regarding the aircraft operator since 3
July 2007
CASA has taken the following actions following the 26 June 2007 incident:
Simultaneously with the ATSB investigation, CASA has conducted a
review of [the operator].
Issued a [Civil Aviation Regulation] CAR 215 direction to the
operator in relation to fuel measurement.
- - 49
Issued a Show Cause Notice (SCN) and Supplementary Show Cause
Notice (SSCN) to the operator:
o The SCN was issued following initial enquiries into the fuel
exhaustion incident at Jundee;
o the enquiries indicated serious deficiencies in the
determination of fuel quantity on board the aircraft and
significant training inadequacies in crew understanding,
identification, implication and handling of engine failure
and asymmetric flight in the approach to land phase of
flight; and
o the SSCN was issued when further investigation led to the
conclusion that there were gross deficiencies within the
organisation in being able to ensure appropriate flight safety
outcomes.
Conducted audits and operational surveillance activities.
Held a show cause conference.
Investigated the chief pilot for administrative anomalies:
o A Part IIIA investigation was not undertaken. Following the
receipt of anecdotal advice that the Chief Pilot's flight and duty
time documents were being altered, CASA issued a demand for
his log book and related documentation to be produced; and
o following review, the anecdotal information could not be
substantiated….
The operator's AOC was varied to include new conditions:
o 34 conditions were appended to the organisation's AOC that
imposed specific requirements upon all the accountable key
personnel and which affected the flight operations, training,
maintenance and safety departments of the organisation19.
Issued CAR 215 direction on aircrew proficiency.
Observed changes in the operations manual that incorporated revised
procedures for:
o Fuel measurement for flight;
o Pilot training; and
o Proficiency check for aircrews.
Following an extensive audit of [the operator], CASA noted that the
company's CEO elected to leave the company.
CASA continues to undertake systems and operational surveillance of [the
operator].
19 The aircraft operator reported that all 34 conditions were addressed and subsequently removed as
conditions on the operator’s Air Operators Certificate.
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ATSB assessment of response/action
The action taken by CASA appears to adequately address the safety issue.
4.2.2 Regulatory guidance for fuel quantity measurement
Safety issue
Regulatory guidance regarding the measurement of fuel quantity before flight
lacked clarity and appropriate emphasis and did not ensure that the fuel quantity
measurement procedures used by operators included two totally independent
methods.
Action taken by the Civil Aviation Safety Authority
On 26 September 2008, CASA advised:
The status of CASA's review of its guidance material relating to separate
processes for fuel quantity measurement checks
The second edition of the Air Transport Communication (AT com)20 advised
of impending amendments to Civil Aviation Advisory Publication (CAAP)
234. In amending CAAP 234, clear guidance will be given to industry
regarding the two independent means of ensuring the correct amount of fuel is
onboard an aircraft.
The amended CAAP 234 will emphasise the responsibilities of the Pilot-in-
Command and the operator in adhering to the manufacturer's guidance in
determining the amount of fuel onboard an aircraft.
CASA would like to emphasise the point that crews utilise all means provided
by the manufacturer to ascertain correct fuel quantity. In this instance there
was a manufacturer's recommended procedure that aircraft fuel quantity is
independently confirmed using a separate facility incorporated into the
aircraft. Had this crew followed that guidance, the incident would not have
experienced its near catastrophic outcome.
The second edition of the AT com advised industry that changes to CAAP
234 were forthcoming. The AT com is intended as an informal means of
raising topical issues inclusive of alerting operators of intended changes.
CASA is not reliant on it to convey the information as variations
documentation is undertaken through our formal process.
The process of amending CAAP 234 is currently being undertaken and this
involves detailed consultation with various stakeholders.
A summary of any changes to CASA regulatory oversight activities relating to
fuel management or fuel quantity cross-checking processes
Fuel quantity cross-checking processes have been added as a distinct element
within operational surveillance activities. Where a deficiency in the fuel cross
checking procedures is identified, it is raised with the operator. The matter
remains under close scrutiny until resolved to the satisfaction of CASA.
20 On 1 March 2009, CASA changed the name of the publication from AT com to CASACom.
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ATSB assessment of response/action
The ATSB is concerned that, at the time of publication of this report, the CAAP
234-1(1) amendment had still not been released. The ATSB will continue to
monitor the progress of the CAAP review.
In addition to the occurrence involving VH-XUE, the ATSB is aware of two other
occurrences involving Australian-registered aircraft since January 2005 involving
engine power loss due to fuel starvation in turboprop aircraft with a maximum take-
off weight (MTOW) above 5,700 kg. In each case, the practices used by the flight
crew to establish fuel quantity did not detect erroneous fuel quantity indications.
The operators involved subsequently amended their procedures to include dripstick
checks as a mandatory part of their procedures for establishing the quantity of fuel
on board the aircraft.
It is possible that there are other examples among turboprop operators of aircraft
with a MTOW greater than 5,700 kg where the procedures used to determine the
quantity of fuel on board the aircraft do not include independent, comparative
checks of fuel quantity. On 14 September 2007, the ATSB issued AO-2007-017-
Safety Advisory Notice-013, which stated:
The ATSB suggests that all turboprop operators take note of the following
safety issue and review their processes accordingly:
The processes used by some turboprop operators for checking the fuel
quantity on board prior to flight have not used two methods of sufficient
independence. In particular, the practice of using a comparison of a gauge
indication after refuelling with the gauge indication prior to refuelling plus the
fuel added is not adequate to detect gradually developing errors in gauge
indications.
On 25 February 2008, the ATSB advised CASA and all Australian operators of
EMB-120 aircraft of the investigation report regarding the EMB-120 engine power
loss occurrence in Europe on 20 February 2008. In the meantime, the ATSB re-
emphasises AO-2007-017-Safety Advisory Notice-013 (above), which was initially
issued on 14 September 2007.
4.2.3 No regulation for simulator training
Safety issue
There was no regulatory requirement for simulator training in Australia.
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Action taken by the Civil Aviation Safety Authority
A summary of CASA activities to facilitate the use of full flight simulators and/or
flight training devices follows:
The following inter-related activities are in the process of implementation:
A combined workshop activity with Ansett Aviation Training,
Capiteq Limited trading as AirNorth, Network Aviation Pty Ltd,
Skippers Aviation Pty Ltd, PelAir Aviation Pty Ltd and CASA was
held on 27, 28 April 2009.
CASA has initiated a review of CAR 217 Training Organisations and
Training Centres. This programme of review was prompted
following investigations that revealed AOC holder training
inconsistencies.
A Component of the 'CAR 217 Training Organisations and Training
Centres Special Emphasis Review' is to establish the level of
company oversight and involvement with training and simulation,
programmes that have been outsourced.
Civil Aviation Order 40.2.1 - Instrument Rating, Section 12A,
`Renewal using an overseas flight simulator training provider' has
been added to include the option of instrument proficiency checks
being conducted by an overseas simulator provider. This is to enable
an instrument rating renewal where a specific type simulator is not
available in Australia:
o This amendment needs to read in conjunction with Advisory
Circular AC 60-2 (1) of May 2007;
o The Advisory Circular identifies that CASA recognises the
flight simulator qualifications certificates issued by Canada,
Hong Kong (Special Administrative Region of China), New
Zealand, the United States of America, Belgium, the Czech
Republic, Denmark, Finland, France, Germany, Ireland,
Italy, the Netherlands, Norway, Portugal, Spain, Sweden,
Switzerland and the United Kingdom; and
o Civil Aviation Order 40.1.0 - Aircraft Endorsement -
Aeroplanes, Section 6. This facilitates an option for
instrument rating renewals to be associated with the issue of
an aircraft type rating.
ATSB assessment of response/action
The activities undertaken by CASA appear to have facilitated increased use of
simulators for endorsement and other training. However, the ATSB remains
concerned that there is no regulatory requirement for simulator training when a
suitable simulator is available in Australia.
ATSB safety recommendation AO-2007-017-SR-084
The Australian Transport Safety Bureau recommends that the Civil Aviation Safety
Authority address this safety issue.
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4.2.4 Requirements for endorsement training
Safety issue
The minimum requirements for endorsement training where simulator training was
not involved did not ensure pilots were aware of indicators and/or aircraft behaviour
during critical emergency situations.
Response from the Civil Aviation Safety Authority
On 28 April 2009, CASA advised as follows:
CASA has identified that there is a risk of interpretive conflict within [Civil
Aviation Order] CAO 40.1.0. As a result, this CAO is under review to identify
further areas of similar risk. Once complete, the results of this review will be
dealt with at the Executive level of CASA.
In amplification of its response, CASA advised that the reference to ‘interpretative
conflict’ related to the requirements in CAO 40.1.0 that made reference to aspects
associated with aircraft complexity (including familiarity ‘with the systems, the
normal and emergency flight manoeuvres and aircraft performance, the flight
planning procedures, the weight and balance requirements and the practical
application of take-off and landing charts of the aircraft to be flown’) compared to
the minimum conditions (flying time) for acting as pilot in command and co-pilot
(see 1.16.1).
ATSB assessment of response
The ATSB acknowledges the information provided by CASA. The ATSB will
monitor the progress of the review of CAO 40.1.0.
4.2.5 Dissemination of safety information
Safety issue
The aircraft operator was not aware of important safety-related information
regarding the EMB-120 fuel system.
Action taken by the Civil Aviation Safety Authority
On 28 April 2009, CASA advised:
The CASA Communication (CASACom) publication, previously known as
the Air Transport Communication (ATCom) has been developed to allow the
Civil Aviation Safety Authority to promptly communicate identified safety
and operational issues to all Air Operator Certificate holders and is available
on the CASA website.
ATSB assessment of response/action
The action taken by CASA appears to adequately address the safety issue.
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4.2.6 Other safety action taken by the Civil Aviation Safety Authority
Although not identified as a safety issue during this investigation, in June 2007,
CASA undertook a review of a number of low capacity air transport operators. The
aim of that review was to enable CASA to prioritise its surveillance of those
operators. A summary of that review, known as the ‘T13 initiative’, follows:
In June 2007, CASA reviewed general aviation operators who were
conducting significant passenger carrying operations, and in relation to which
oversight responsibilities were due to be transferred from the General
Aviation Operations Group (GAOG) to the Air Transport Operations Group
(ATOG) in December 2007. The original list comprised of 19 operators, but
this was subsequently reduced to 13. The review assessed the risk of each
operator to assist in prioritising future surveillance of the operators. [The
operator] was not part of this process.
4.3 Aircraft certification authorities
4.3.1 Fuel low level warning
Safety issue
The certification standard to which the aircraft was built did not require the aircraft
to be equipped with a fuel low level warning system.
Action taken by other investigating bodies
The investigation of a number of similar occurrences by the Irish Air Accident
Investigation Unit (AAIU), the Italian Agenzia Nazionale per la Sicurezza del Volo
(ANSV), and the UK Air Accident Investigation Branch (AAIB) identified a similar
safety issue. In each case, the response by those investigation agencies was to issue
safety recommendations that sought the enhancement of the relevant certification
standards to require the installation of independent fuel low level warning systems
in turboprop and turbojet aircraft.
ATSB assessment of response/action
The recommendations by the Irish AAIU, Italian ANSV, and the UK AAIB appear
to adequately address this safety issue.
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4.4 Aircraft manufacturer
4.4.1 Dissemination of safety information
Safety issue
The aircraft operator was not aware of important safety-related information
regarding the EMB-120 fuel system.
Action taken by Empresa Brasileira de Aeronáutica S.A.
The aircraft manufacturer confirmed that any issues submitted to the Air Safety
Department were analysed for possible impact on other operators and disseminated
via Air Safety Representative located around the world. They disseminated
information, to all operators, of the two events that were advised of and
subsequently sought details of the third event once there were aware of it.
ATSB assessment of response/action
The action taken by Empresa Brasileira de Aeronáutica S.A. appears to adequately
address the safety issue.
4.4.2 Other safety action taken by the aircraft manufacturer
As a result of this and other similar EMB-120 incidents, the following safety
actions were also taken by the aircraft manufacturer in order to provide additional
guidance to flight crews.
Amendment to maintenance manuals
At the time of the occurrence, the Empresa Brasileira de Aeronáutica S.A. EMB-
120 Maintenance Manual included a section titled Fuel Quantity Indication System
– Inspection/Check. The manual required a general visual inspection of the fuel
quantity indication system wiring harness to be conducted and stated that if repair
was required, the procedures detailed in the aircraft Wiring Manual should be
followed.
In April 2007, the manufacturer amended the wiring manual to include the
following:
CAUTION
DO NOT PERFORM ANY KIND OF REPAIR TO WIRES OR CABLES
INSIDE FUEL TANKS.
4. Splicing Fuel Critical Cables
WARNING: DO NOT REPAIR THE FUEL CRITICAL CABLE HARNESS.
IF YOU DO NOT OBEY THIS PRECAUTION, AN EXPLOSION CAN
OCCUR IN THE FUEL TANKS.
A. Replace the whole segment of damaged fuel critical cables. Splicing fuel
critical cables is not permitted.
- - 56
On 17 March 2008, Embraer issued Service newsletter (SNL) 120-28-0008 which
‘...inform[s] the operators about the instructions for the FQIS in-tank harness
installation, in order to avoid the possibilities of FQIS wiring chafing with other
components installed in the fuel tanks’. A copy of that newsletter is at Appendix D.
Flight crew procedures in the event of engine failure
On 14 May 2008, the manufacturer issued Operational Bulletin No 120 – 001/08
that was applicable to all EMB-120 aircraft operated under ANAC (Agência
Nacional de Aviação Civil (Brasil)) certification.
II - SUBJECT: ENGINE FAILURE ABNORMAL PROCEDURE
III - REASON:
This Operational Bulletin is being issued to provide the EMB-120 operators
under ANAC certification with a revised engine failure abnormal procedure.
IV - BACKGROUND INFORMATION:
Instances have been reported to EMBRAER of difficulties to perform a one
engine inoperative go-around after an engine failure during final approach.
Such difficulties are related to the fact that the propeller of the affected side
had not been confirmed feathered before the airplane was commanded to
perform the go-around.
Current ANAC approved EMB-120 Airplane Flight Manual (AFM) Engine
Failure abnormal procedure already addresses the event of an engine failure.
Nevertheless, since the mentioned engine failure event may require flight
crew action before the level-off altitude is reached, case in which the checklist
is consulted by the flight crew, EMBRAER understands that the current
ANAC approved EMB-120 AFM Engine Failure abnormal procedure needs
to be revised in order to include memory item steps.
It is EMBRAER recommendation that all EMB-120 operators do adequate
flight crew update training regarding this revision to the Engine Failure
abnormal procedure.
V - OPERATING INFORMATION:
If an engine failure occurs, the following procedure must be observed:
ENGINE FAILURE
1. Power Lever (affected engine) .....................FLT IDLE
2. Condition Lever (affected engine) ................FEATHER, AND THEN
CHECK
3. ELEC FEATHER Switch..............................ON, THEN CHECK
PROPELLER FEATHERING
Precautionary Engine Shutdown .......................PERFORM
CAUTION: IF DET INOP ENG/WW OR DET INOP PIPE ZONE LIGHT
ILLUMINATES SIMULTANEOUSLY WITH ENGINE FAILURE, APPLY
ENGINE FIRE PROCEDURE.
VI - TECHNICAL PUBLICATION INFORMATION:
- - 57
The Airplane Flight Manual (AFM-120/813) and the Quick Reference
Handbook (QRH-120/1023) will be revised to incorporate this information.
4.5 Ansett Aviation Training
4.5.1 No EMB-120 flight simulator training facility in Australia
Although not identified as a safety issue, as a result of this investigation, on 15
April 2009, the following advice was received from Ansett Aviation Training in
regard to the availability of an EMB-120 flight simulator training facility in
Australia:
Until recently it was cost prohibitive for many operators to consider full flight
simulator training for their flight crew, as most of the simulator devices were
located overseas. The owners of Ansett Aviation Training recently invested in
access of 35 million dollars creating the largest pilot training and simulator
centre in the Southern Hemisphere. During the development stage of the new
centre, CASA indicated that there would be legislation introduced that would
require operators to utilize full flight simulators for pilot training should these
devices be located in Australia. The selection of full flight simulators for the
centre was driven by this planned requirement together with the subsequent
commercial viability of each device. The Embraer 120, Fokker F100 and the
King Air 200 full flight simulators were purchased and CASA certified the
devices for endorsement and other pilot training requirements.
It is evident looking at the Australian regional airline industry and aerial work
operators, that following the pilot shortage of the previous few years, the
experience level of the pilot work force is low. Experience pilots flowed
through to the major airlines and young inexperienced pilots were taken on by
the regional airlines. Our experience has been that most of these young pilots
have never been inside a full flight simulator and are not aware of the training
advantages of these devices. In some instances, the chief pilot and training
managers have never trained in a full flight simulator and have not
experienced the level of training that can be achieved.
This situation resulted in Ansett Aviation Training programming educational
workshops for operators of aircraft types applicable to our full flight
simulators. A successful workshop was held some time ago to promote full
flight simulator training in the Metro III/23 simulator and this resulted in
many operators now using this device for their pilot training needs. A
workshop and discussion forum is planned for Embraer 120 aircraft operators
and is scheduled for the 28th April 2009. The workshop will introduce the full
flight simulator over a number of sessions over the two days demonstrating
some of the 225 separate malfunctions possible on the device. We will be
looking at standardization of training and syllabus and to look at identifying
those check and training personnel who need to be familiar with the operation
of the simulator for their own needs. All EMB 120 operators have indicated
that they will take part and each operator will be sending several key training
personnel for the two day forum. We have also included the Embraer aircraft
representative for the Asia Pacific region and are endeavouring to acquire the
attendance of representatives from operator insurance companies. [A] CASA
Internal Audit and Standards Officer will be attending and addressing the
forum…
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We have completed analysis into the real cost of aircraft training verses full
flight simulator training. It is easy to show that even when taking into account
airfares, accommodation and allowances for aircrew, simulator training is the
cheaper option. Often an operator will only look at initial operating costs such
as fuel etc to determine the viability of aircraft training verses simulator
training. This is not a true determination when all aircraft operating costs,
including maintenance, insurance, depreciation, air navigation charges and
aircraft re-scheduling and crew costs are taken into consideration. I believe
that any legislation requiring simulator training for aircrew will not be an
added financial burden to operators.
On 28, 29 April 2009, a workshop and discussion forum to introduce the new
Embraer Brasilia simulator involving all Australian operators of EMB-120 aircraft
was held at the Ansett Aviation Training facility. Subsequently, flight crew training
on the EMB-102 simulator began. Flight crew from the operator of XUE were
among the first crews to undertake training in the EMB-120 simulator.
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APPENDIX A: FUEL LOW LEVEL WARNING SYSTEMS: PREVIOUS OCCURRENCES AND RECOMMENDATIONS
The EMB-120 aircraft was designed under Part 25 of the US Federal Aviation
Regulations (FARs). Although fuel low level warning systems are not specifically
required for Part 25 aircraft, many aircraft in that category are equipped with those
systems. In some cases, however, the design of those systems has been questioned
following fuel quantity indicating systems being implicated in air safety
occurrences.
For example, in an investigation into a British Aerospace J-31 accident (21 May
2000)21, the US National Transportation Safety Board (NTSB) noted that the
aircraft was equipped with low fuel quantity lights for each tank on the instrument
panel. However, the position and characteristics of the lights meant that they could
be easily overlooked, even when illuminated.
An Irish Air Accident Investigation Unit (AAIU) report into an ATR-42 incident (8
August 2003)22 found that, although that aircraft had fuel low level warning, the
warning was not independent of the fuel gauges. The final investigation report
(August 2005) included the following recommendation:
The European Air Safety Agency (EASA) should review the certification
criteria for public transport aircraft low fuel contents warning systems, with a
view to requiring such systems to be independent of the main contents
gauging systems.
The Italian safety investigation agency, Agenzia Nazionale per la Sicurezza del
Volo (ANSV), issued a similar recommendation to EASA following the accident
involving an ATR-72 offshore of Palermo Airport (6 August 2005).23
21 NTSB Accident No. DCA00MA052, Executive Airlines, British Aerospace J-31, N16EJ, Bear
Creek Township Pennsylvania, 21 May 2000. The right engine stopped due to fuel starvation and
there was intermittent stoppage of the left engine due to fuel starvation. Due to communication
problems, the crew probably thought more fuel had been added to the tanks prior to the last flight
than was actually added. The 19 people on board were fatally injured.
22 AAIU Formal Report No: 2005-014, Serious Incident to ATR 42, EI-CBK, near Dublin, 8 August
2003. During a regular passenger flight, the right engine stopped due to fuel starvation. The crew
declared an emergency and diverted the flight for an uneventful single-engine landing. The fuel
gauge had been providing erroneous indications for several weeks prior to the incident.
23 The final report for this accident has not been released. The ATR-72 aircraft ditched after both
engines ceased operating due to fuel exhaustion. At the time, the fuel quantity indicator (FQI) was
indicating 1,800 kg even though the fuel tanks were empty. That situation arose because the FQI
had been replaced with one applicable to ATR-42 model aircraft. Of the 39 people on board, 16
were fatally injured.
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Following an incident involving an Airbus Industrie A340 aircraft (8 February
2005)24, the UK Air Accident Investigation Branch (AAIB) issued four
recommendations relating to low fuel level warning systems. These were:
AAIB Safety Recommendation 2005-108: It is recommended that the
European Aviation Safety Agency introduces into CS-25 the requirement for
a low fuel warning system for each engine feed fuel tank. This low fuel
warning system should be independent of the fuel control and quantity
indication system(s).
AAIB Safety Recommendation 2005-109: It is recommended that the
European Aviation Safety Agency should review all aircraft currently
certified to EASA CS-25 and JAR-25 to ensure that if an engine fuel feed low
fuel warning system is installed, it is independent of the fuel control and
quantity indication system(s).
AAIB Safety Recommendation 2005-110: It is recommended that the USA’s
Federal Aviation Administration should introduce into FAR-25 a requirement
for a low fuel warning system for each engine feed fuel tank. This low fuel
warning system should be independent to the fuel control and quantity
indication system(s).
AAIB Safety Recommendation 2005-111: The Federal Aviation
Administration should review all aircraft currently certified to FAR-25 to
ensure that if an engine fuel feed low fuel warning system is installed, it is
independent of the fuel control and quantity indication system(s).
EASA responded to the AAIB, stating that it agreed with the recommendations and
was developing plans to amend the relevant legislation by 2009. The AAIB
accepted EASA’s responses.
In its response to AAIB recommendation 2005-110, the FAA stated25:
As noted within the Discussion section of the AAIB Safety Recommendation
(File Ref:EW/C2005/02/03): ''It could be argued that the need to indicate fuel
system failures to the crew on complex aircraft is covered by EASA CS-25
1309 para c.'' The AAIB goes on to state that: ''Indeed, when the fuel control
system is operating normally on the A340-600 this is true, but this incident
demonstrated a need for more specific requirements for certain warnings such
as low fuel level in an engine feeder tank''.
24 AAIB Report on the incident to Airbus A340-642, registration G-VATL en-route from Hong
Kong to London Heathrow on 8 February 2005. The number one engine lost power and ran down
due to fuel starvation. A few minutes later, the number four engine started to lose power. Fuel had
not been transferring from the centre, trim and outer wing tanks to the inner wing tanks due to a
computer problem. Although transfer was partially achieved, the expected indications of fuel
transfer in progress were not displayed so the commander decided to divert to Amsterdam where
the aircraft landed safely on three engines.
25 AAIB, Progress Report 2007: Responses to Air Accidents Investigation Branch (AAIB) Safety
Recommendations, pp.8-9.
- - 61
Compliance with 25.1309 (c) is just as relevant during any anticipated failure
condition as it is when the system is operating normally. Traditional designs
may not have effectively met the intent of 25.1309 (c)26 for certain ''unsafe
system operating conditions'', including ''low fuel level in an engine feeder
tank''. As evidenced by the Notice of Proposed Rulemaking (NPRM) (NO.
87-3) published in the Federal Register on May 12, 1987 (52 FR 17890), titled
''Low Fuel Quantity Alerting System Requirements for Transport Category
Airplanes'' the FAA once agreed with the AAIB that this ''demonstrated a
need for more specific requirements''.
While adding a more specific rule may focus special attention and unique
provisions onto a particular ''unsafe system operating condition'' , it will not
relieve an applicant of the obligation of complying with 25.1309 (c) for that
condition. After considering the comments from NPRM 87-3 and reviewing
all the relevant service history, the FAA has concluded that there is no need
for any new regulatory provisions in this case. The addition of a more specific
requirement will be redundant to those regulatory objectives already covered
by 25.1309 (c). Furthermore, promulgation of a more specific requirement
could inadvertently impede future design innovation and would not be an
efficient use of our limited rulemaking resources.
The FAA now intends to develop clearer 25.1309 (c) compliance guidance in
the form of an interpretive policy on this issue. Successful completion of that
action would effectively address FAA Safety Recommendation 06.006.
The AAIB classified this response, and the FAA response to recommendation 2005-
111, as ‘Rejected’.
26 US Federal Aviation Regulation 25.1309 (Equipment, systems, and installations), paragraph (c)
stated: Warning information must be provided to alert the crew to unsafe system operating
conditions, and to enable them to take appropriate corrective action. Systems, controls, and
associated monitoring and warning means must be designed to minimize crew errors which could
create additional hazards.
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APPENDIX B: FUEL STARVATION-RELATED OCCURRENCES INVOLVING AUSTRALIAN REGISTERED AIRCRAFT OTHER THAN EMB-120 AIRCRAFT SINCE JANUARY 2005
Fairchild Metro III, 23 September 2005 (BO/200504768)27
At 1910 Eastern Standard Time on 23 September 2005, a Fairchild Industries Inc.
Model SA227-AC (Metro III) aircraft, registered VH-SEF, departed Thangool on a
scheduled flight to Brisbane, Qld. There were two pilots and 16 passengers on
board. Approaching overhead Gayndah, the L XFER PUMP (left fuel transfer
pump) amber caution light illuminated, indicating low fuel quantity. The fuel
quantity indicator showed substantial fuel in the tanks. The crew completed the
checklist actions but the light remained on so they diverted the flight to Bundaberg.
About 18 km from Bundaberg, the left engine stopped. The crew subsequently
completed a single-engine landing at Bundaberg.
Four pounds (2 L) of fuel was subsequently drained from the left tank, indicating
that the left engine stopped because of fuel starvation. There was 49 lbs (28 L) of
fuel in the right tank, sufficient for about 10 minutes flight.
Faults were found in a number of components of the fuel quantity indicating
system. The maintenance manual procedures for calibration of the fuel quantity
indicating system had not been followed correctly on two occasions in the previous
10 days. The result was that the fuel quantity indicating system was over-reading.
The crew relied on the fuel quantity indicator to determine the quantity of fuel on
the aircraft before the flight. That practice was common to most of the operator’s
crews. The fuel quantity management procedures and practices within the company
did not ensure validation of the aircraft’s fuel quantity indicator reading. There was
also no system in place to track the aircraft’s fuel status during and after
maintenance. The aircraft type was fitted with dripsticks.
Boeing Co B747-338, 5 February 2007 (BO/200700368)28
On 5 February 2007, the crew of a Boeing Co 747-338, registered VH-EBY,
shutdown the number 3 engine in flight, due to a fuel-related problem,
approximately 256 km from the destination airport.
Approaching the top of descent, the crew noticed that the number 3 main fuel tank
quantity indicator was reading zero, and that both fuel-boost pump low pressure
lights had illuminated. The crew then shut down the number 3 engine, declared a
PAN and the flight continued for an uneventful landing at Melbourne.
The subsequent investigation by engineering personnel found that the number 3
main fuel tank was empty. An ‘over read’ malfunction in the number 3 fuel quantity
27 The final safety investigation report is available at
http://www.atsb.gov.au/publications/investigation_reports/2005/AAIR/aair200504768.aspx
28 The final safety investigation report is available at
http://www.atsb.gov.au/publications/investigation_reports/2007/AAIR/aair200700368.aspx
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indicator system (FQIS) had caused the crew to believe there was a greater quantity
of fuel remaining in that tank than was actually present. The planned quantity of
fuel for arrival at Melbourne for the number 3 tank was 2,500 kg. The investigation
determined that the malfunction was caused by either an electrical malfunction,
water contamination or a combination of both.
The FQIS system fault was rectified and the aircraft returned to service.
Investigation by the operator’s safety group found that the refuelling procedures
current at the time were not able to accurately verify the base line quantity of fuel
on board, or to alert the flight crew or line engineers to the consequences of an
erroneous FQIS indication. The investigation also reviewed the refuelling
procedures for all other of the company fleet types to ensure serviceability of those
installations. As a consequence a series of recommendations were made requiring
amendments to the published refuelling procedures and including revision of the
risk management process, intended to prevent a possible recurrence of the incident
events.
Cessna Aircraft Company C404 Titan, 18 October 2007 (AO-2007-049)29
On 18 October 2007, the pilot of a Cessna Aircraft Company C404 Titan aircraft
was conducting a charter flight from Adelaide Airport, SA to Parafield Airport,
Beverley airstrip, and return to Adelaide. The pilot had commenced descent into
Adelaide on the final sector of the flight when the right engine lost power. There
were no apparent anomalies and the fuel quantity gauges were showing adequate
fuel in each tank. After securing the right engine, the pilot continued to Adelaide
Airport and landed without further incident.
Aircraft maintenance engineers who inspected the aircraft reported that 3 L of fuel
was drained from the right tank and 90 L was drained from the left tank. The fuel
quantity gauge was indicating 150 lbs (95 L) in the right tank. An engineer found
that one of the electrical circuits in the right fuel quantity indicating system had a
high resistance. After wiring in the circuit was repaired, the fuel quantity gauge
correctly indicated zero fuel in the right tank. Calibration of the fuel quantity
indicating system was carried out and during that process, the left and right signal
conditioners were found to be unreliable and were replaced or repaired.
The operator amended its fuel documentation and fuel planning procedures to
include a secondary means of verification of fuel on board to cross check the
electric fuel indication system.
Fairchild Metro III, 20 December 2007
The pilot in command submitted the following report to the ATSB:
After my arrival it was discovered that the aircraft had been refuelled twice
and by fuel records alone 3,500 lbs of fuel should have been on board. The
fuel flow totaliser indicated that 200 lbs of fuel had been used. It was assumed
that this amount was used during engine ground running for maintenance
purposes. As a result the fuel on board should have been 3,300 lbs.
29 The final safety investigation report is available at
http://www.atsb.gov.au/publications/investigation_reports/2007/AAIR/aair200706444.aspx
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The serviceable left tank fuel gage indicated 1,100 lbs of fuel [the right fuel
gauge was unserviceable as per the aircraft MEL], well short of the expected
value of 1650lbs. Both tank fuel quantities were checked utilizing the Magna-
stick which indicated that at least a total of 2,100 lbs of fuel was in the fuel
tanks. (The magna-sticks are only accurate between 130 and 1,050 lbs of
fuel/tank) Endurance was planned on 2,100 lbs of fuel, performance was
planned on the fuel record value of 3,300 lbs and the flight conducted without
incident.
After landing, the magna-sticks revealed that 1,100 lbs of fuel remained in the
tanks. Based on the fuel used for the flight of 1,300 lbs and the fuel
remaining, we had departed Brisbane with 2,400lbs of fuel some 900 lbs of
fuel less than the flight record sheet suggested.
I contacted … to enquire if any maintenance had been performed on the fuel
tanks … and was told that both tanks had been drained into... to enable fault
finding on the unserviceable right fuel gauge.
As the fuel remaining figure of 1,000 lbs on flight record sheet 59278 [from
the previous flight] had been drained this explains the discrepancy of 900 lbs
of fuel.
It appears that we have no system in place to track the aircrafts fuel status
during and after maintenance.
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APPENDIX C: RECENT SERIOUS OCCURRENCES INVOLVING TRANSPORT CATEGORY TURBOPROP AIRCRAFT IN AUSTRALIA WHERE AIRCRAFT HANDLING WAS A FACTOR
Fairchild Industries Inc SA227-AC, VH-NEJ, Tamworth, NSW
16 September 1995
The flight was the second Metro III type conversion training flight for the copilot.
Earlier that night, he had completed a 48-minute flight.
During the briefing prior to the second flight, the check-and-training pilot indicated
that he would give the copilot a V1 cut during the takeoff. The copilot questioned
the legality of conducting the procedure at night. The check-and-training pilot
indicated that it was not illegal because the company operations manual had been
amended to permit the procedure. The crew then proceeded to brief the instrument
approach, which was to be flown following the V1 cut. There was no detailed
discussion concerning the technique for flying a V1 cut.
The copilot conducted the takeoff. Four seconds after the aircraft became airborne,
the check-and-training pilot retarded the left engine power lever to flight idle. The
landing gear was selected up 11 seconds later. After a further 20 seconds, the
aircraft struck the crown of a tree and then the ground about 350 m beyond the
upwind end of the runway and 210 m left of the extended centreline. It caught fire
and was destroyed. The copilot and another trainee on board the aircraft were killed
while the check-and-training pilot received serious injuries.
The investigation found that the performance of the aircraft was adversely affected
by:
• the control inputs of the copilot; and
• the period the landing gear remained extended after the simulated engine failure.
The check-and-training pilot had flown night V1 cut procedures in a Metro III flight
simulator, but had not flown the procedure in the aircraft at night. He did not
terminate the exercise, despite indications that the aircraft was not maintaining V2
and that it was descending. There were few external visual cues available to the
crew in the prevailing dark-night conditions. This affected their ability to maintain
awareness of the aircraft's position and performance as the flight progressed.
A number of organisational factors were identified which influenced the aviation
environment in which the flight operated. These included, on the part of the
operating company:
• an inadequate Metro III endorsement training syllabus in the company
operations manual;
• inadequate assessment of the risks involved in night V1 cuts; and
• assigning the check-and-training pilot a task for which he did not possess
adequate experience, knowledge, or skills.
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Organisational factors involving the regulator included:
• a lack of enabling legislation prohibiting low-level night asymmetric operations;
• deficient requirements for copilot conversion training;
• inadequate advice given to the operator concerning night asymmetric operations
and the carriage of additional trainees on training flights;
• deficient training and approval process for check-and-training pilots; and
• insufficient quality control of the company operations manual.
The investigation also determined that there was incomplete understanding within
the company, the regulating authority, and some sections of the aviation industry of
the possible effects of engine flight idle torque on aircraft performance. Inadequate
information on the matter in the aircraft flight manual contributed to this.
The complete report can be viewed at:
http://www.atsb.gov.au/publications/investigation_reports/1995/AAIR/aair1995030
57.aspx
Beech 1900D Airliner, VH-NTL, Williamtown, NSW 13 February 2000
On 13 February 2000 a Beech 1900D Airliner, VH-NTL, was on a local training
flight. The pilot in command simulated a failure of the left engine shortly after
takeoff by retarding the left power lever to the 'FLIGHT IDLE' position. The
handling pilot applied full right rudder and right aileron to counter the resultant yaw
to the left, but the yaw continued until power was restored to the left engine to
regain directional control. In the 21 seconds following takeoff, the aircraft did not
climb above 160 ft above ground level, and at one stage had descended to 108 ft.
The aircraft was then climbed to a height of 2,000 ft where the pilot in command
simulated another failure of the left engine by retarding its power lever to the
'FLIGHT IDLE' power setting. The aircraft again lost controllability. Power was
restored to the left engine, and the aircraft landed without further incident.
There was no evidence that any aircraft or systems malfunctions contributed to the
controllability problems experienced by the crew during the occurrence flight.
Since 1992, it was the practice of the operator's check pilots to simulate one-engine
inoperative by retarding the power lever of the 'failed' engine to 'FLIGHT IDLE'.
That was contrary to the procedure prescribed in the Federal Aviation Authority-
approved Beech 1900D Airplane Flight Manual, and also to that specified in the
operator's Civil Aviation Safety Authority-approved Training and Checking
Manual. Reducing power to 'FLIGHT IDLE' also had the effect of simulating a
simultaneous failure of the engine and its propeller auto-feather system. The
simulation of simultaneous in-flight failures was contrary to the provisions of the
CASA-approved Training and Checking Manual. During each of the simulated one-
engine inoperative sequences, control of the aircraft was not regained until the
power on the 'failed' engine was advanced to the manufacturer's prescribed one-
engine inoperative thrust power setting.
The operator's training and checking organisation and its check pilots were aware
that the likely consequences of simulating an engine failure by retarding its power
to less than zero thrust were reduced aircraft climb performance and increased air
minimum control speed (V MCA ). They were also aware that risk increased when
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in-flight training exercises involved the simulation of multiple failures. The
prescribed procedures were therefore necessary defences to minimise those risks.
The circumvention of those defences significantly increased the risks associated
with the operator's training and checking procedures, and was a safety-significant
concern. This occurrence demonstrated the potentially serious consequences of
degraded aircraft performance by setting 'FLIGHT IDLE' to simulate one-engine
inoperative. The practice has the potential to jeopardise the safety of flight and
should be strongly discouraged.
The ATSB's investigation established that the failure to achieve predicted
performance during take-off and subsequent climb was the result of an incorrect
procedure. As a result of this serious occurrence, the ATSB recommended that the
Civil Aviation Safety Authority (CASA) publish information for the guidance of
operators and pilots regarding the correct procedures for simulating engine failures
in turbo-propeller aircraft. CASA advised that it will publish an amendment to Civil
Aviation Advisory Publication 5.23-1(0) to highlight appropriate engine-out
training procedures in turbo-propeller aircraft. CASA also advised that it would
ensure that operators' manuals contained appropriate procedures for the conduct of
multi-engine training, and that it would draw attention to those procedures during
forthcoming safety promotion activities. The operator advised that it had instructed
its check pilots that an engine's power lever must not be retarded below the zero
thrust torque setting when simulating an engine failure on takeoff, and that those
simulations were not be carried out until the aircraft had reached 250 ft above
ground level.
The complete report can be viewed at:
http://www.atsb.gov.au/publications/investigation_reports/2000/AAIR/aair2000004
92.aspx
Beech Aircraft Corporation King Air C90, VH-LQH, Toowoomba, Qld
27 November 2001 (abbreviated summary)
At about 0836 Eastern Standard Time on 27 November 2001, a Beech Aircraft
Corporation King Air C90 aircraft, registered VH-LQH, took off from runway 29 at
Toowoomba aerodrome, Queensland for an Instrument Flight Rules charter flight to
Goondiwindi, Queensland. On board were the pilot and three passengers.
Just prior to, or at about the time the aircraft became airborne, the left engine failed.
A subsequent examination of the left engine found that it probably lost thrust-
producing power almost immediately. Following the engine failure, the take-off
manoeuvre continued and the aircraft became airborne prior to crashing.
The aircraft was equipped with an automatic propeller feathering system, but the
propeller was not feathered at impact. The reason the propeller was not feathered
could not be determined. The landing gear was not retracted during the short flight.
The right engine was developing significant power at impact.
The aircraft remained airborne for about 20 seconds. The aircraft’s flight path was
typical of an asymmetric, low speed flight situation, and it is unlikely that the
aircraft’s speed was ever significantly above the minimum control speed (Vmca) of
90 kts. The aircraft manufacturer’s specified procedures for responding to an engine
failure in LQH stated that the take off should be rejected below the ‘take-off speed’,
specified as 100 kts. After control of the aircraft was lost, and as the aircraft was
rolling through about 90 degrees left bank, it struck powerlines about 10 m above
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ground level and about 560 m beyond the end of the runway. It then continued to
roll left and impacted the ground inverted in a steep nose-low attitude. An intense
fuel-fed fire erupted upon initial impact with the ground. The aircraft was destroyed
and all four occupants sustained fatal injuries. The accident was not considered to
be survivable due to the impact forces and post-impact fire.
Flight operations issues
The investigation determined that the pilot was appropriately licensed to conduct
the flight, and that it was unlikely that any medical or physiological factor’s
adversely affected the pilot’s performance. There was also no evidence that
incorrect aircraft loading or meteorological conditions were factors in the accident.
Several factors would have contributed to the aircraft’s speed not being sufficient
for the pilot to maintain control of the aircraft during the accident flight. These
factors included the significant loss of power from the left engine just prior to, or at
about the time, the aircraft became airborne, and the substantial aerodynamic drag
resulting from the landing gear remaining extended and the left propeller not being
feathered. In addition, the aircraft’s speed when it became airborne was probably
close to Vmca and not sufficient to allow the aircraft to accelerate to the best one-
engine inoperative rate-of-climb speed (Vyse) of 107 kts with an engine failure.
With an engine failure or malfunction near Vmca, the safest course of action would
be to reject the takeoff due to the likelihood of the aircraft not being able to
accelerate to Vyse. Although in some cases this will mean that the aircraft will
overrun the runway and perhaps sustain substantial damage, the consequences
associated with such an accident will generally be less serious than a loss of control
after becoming airborne.
In this case, the engine failure occurred during a critical phase of flight, in a
situation that was among the most difficult for a pilot to respond to in a manner that
would ensure a safe outcome. In addition to the timing of the engine failure, a
number of factors could have influenced the pilot’s decision to continue with the
takeoff, including the nature of the operator’s procedures, the length of the runway,
and the visual appearance of the runway and buildings beyond the runway at the
time of the engine failure.
The operator specified a rotation speed of 90 kts, which was less than the 96 kts
rotation speed specified by the aircraft manufacturer for King Air C90 aircraft. The
operator’s specified rotation speed had the effect of degrading the one-engine
inoperative performance capability of the aircraft during takeoff. In addition, the
operator’s procedures did not provide appropriate guidance for pilots regarding
decision speeds or decision points to use for an engine failure during takeoff.
While aircraft manufacturers have provided guidance material in operating manuals
regarding engine failures leading to power loss in multi-engine aircraft, CASA had
not published formal guidance material. The level of training available for
emergencies in this category of aircraft during critical phases of flight and at high
aircraft weights was less than desirable.
Toowoomba aerodrome was licensed and met the relevant CASA standards.
However, runway 29 did not meet the ICAO standard in relation to the runway end
safety area (RESA).
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Safety action
Since the accident, CASA has made changes to the requirements of AD/ENG/5 and
the processes for assessing the suitability of maintenance controllers.
As a result of this investigation, the ATSB issued six recommendations to CASA
including the following:
• the provision of formal advisory material to operators and pilots about managing
engine failures and other emergencies during takeoff.
• the assessment of synthetic training devices for the purpose of training pilots in
making decisions regarding emergencies during critical stages of flight.
The complete report can be viewed at:
http://www.atsb.gov.au/publications/investigation_reports/2005/AAIR/aair2005070
77.aspx
Fairchild Industries SA227-AC Metro III, VH-TAG, 33km ENE Canberra,
ACT 21 November 2004
On 21 November 2004, the crew of a Fairchild Industries SA227-AC Metro III
aircraft, registered VH-TAG, was conducting an endorsement training flight near
Lake George, 33 km north-east of Canberra Airport. The flight included a planned
in-flight engine shutdown and restart, conducted at an altitude below 4,500 ft (about
2,200 ft above ground level (AGL)). During the engine restart preparation, the
instructor departed from the published procedure by moving the power lever for the
left engine into the beta range and directing the pilot to select the unfeather test
switch. These actions were appropriate to prepare an engine for start on the ground
with a feathered propeller, but not during an airstart. As a result, the propeller on
the left engine became fixed in the start-locks position. The crew lost control of the
aircraft and it descended 1,000 ft, to about 450 ft AGL, before they regained
control. The crew could not diagnose the source of the loss of control and
proceeded to start the left engine while the propeller was fixed on the start-locks.
As a result, the crew lost control of the aircraft for a second time and it descended
1,300 ft, to about 300 ft AGL, before they regained control. The SA226 / SA227
aircraft contain no lockout system to prevent pilots from intentionally moving the
power lever into the beta range during flight. It was the first time the instructor had
given a Metro endorsement and he was subject to time pressure to complete the
endorsement. His ongoing difficulties in adapting to his employment tasks were not
successfully dealt with by the operator. He had a limited understanding of the
aircraft's engine and propeller systems, and had not practiced an airstart for eight
years as the CASA check and training approval did not include an assessment of all
flight critical exercises.
The complete report can be viewed at:
http://www.atsb.gov.au/publications/investigation_reports/2004/AAIR/aair2004045
89.aspx
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APPENDIX D: EMBRAER SERVICE NEWSLETTER
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APPENDIX E: SOURCES AND SUBMISSIONS
Sources of information
The sources of information during the investigation included:
the flight crew of VH-XUE
the operator of VH-XUE
the aircraft manufacturer
the Civil Aviation Safety Authority (CASA)
Ansett Aviation Training.
Submissions
Under Part 4, Division 2 (Investigation Reports), Section 26 of the Transport Safety
Investigation Act 2003, the Executive Director may provide a draft report, on a
confidential basis, to any person whom the Executive Director considers
appropriate. Section 26 (1) (a) of the Act allows a person receiving a draft report to
make submissions to the Executive Director about the draft report.
A draft of this report was provided to CASA, the operator, the pilots, the aircraft
manufacturer, the accredited representative from the country of manufacture, and
Ansett Aviation Training.
Submissions were received from the operator, the aircraft manufacturer, CASA and
Ansett Aviation Training. The submissions were reviewed and where considered
appropriate, the text of the report was amended accordingly.